KR20170142061A - Certification apparatus and certifying method thereof - Google Patents

Abstract

The present invention provides an authentication device which improves security and has various advantages such as short distance/high speed/recognition speed of a near field communication (NFC). The authentication device comprises: a storage part storing user information including biometric signal information; a sensor part recognizing the biometric signal information of a user; an NFC control part converting the biometric signal information into an NFC function-on state when the user authentication is successful by comparing the recognized biometric signal information with the stored biometric signal information; and an NFC antenna part transmitting/receiving a wireless signal with an NFC reader. The NFC control part processes the wireless signal transmitted/received by the NFC antenna part only when the NFC function is on.

Description

[0001] Certification apparatus and certifying method [0002]

The present invention relates to a biometric authentication system, which comprises a storage unit for storing user information including biometric signal information, a sensor unit for recognizing the biometric signal information of the user, and an authentication unit for comparing the recognized biometric signal information with the stored biometric signal information, an NFC controller for converting an NFC antenna into an on state and an NFC antenna for transmitting and receiving a radio signal to and from an NFC reader, And an authentication method therefor.

Near Field Communication (NFC) is one of RFID (Radio Frequency Identification) technologies and corresponds to a contactless communication technology using a frequency band of 13.56 MHz. NFC is a technology for wireless communication with a very short distance of 10cm or less. Because of its short communication distance, NFC is attracting attention as a next generation short range communication technology because of its relatively high security and low cost. In particular, it is superior in security and convenience compared to Bluetooth or ZigBee, and can use both data reading and writing functions, and can be used in various services in everyday life.

Particularly, in the case of NFC, information can be exchanged through wireless communication at a short distance. As a result, it can support high-bandwidth communication that provides near-field data communication between devices equipped with NFC, and can support various functions such as card emulation, reader mode and P2P mode. In addition, it enables fast terminal recognition time of around 0.1 second, and high speed transmission of about 400 Kbps is possible.

1 and 2, in the case of a card including a conventional NFC chip, an NFC controller 110 may be connected to the NFC antenna unit 120, or an NFC antenna or an NFC antenna may be connected to the chip 220 embedded in the card. NFC controller. Therefore, if you want to use the NFC function, you can use it after recognizing the chip by approaching the reader.

However, in the case of NFC technology, the security of the card including the NFC chip itself is rented or lost although the security of the NFC technology is higher than that of the other communication by directly tagging by the user who holds the card. And there is a disadvantage that it can be easily copied.

Accordingly, there is a need to develop a security card module that has merits of NFC technology while further enhancing security by complementing security weaknesses of the conventional NFC chip module.

It is an object of the present invention to provide an authentication device having various advantages such as a short range / high speed / recognition speed of NFC while improving security as described above.

The technical problem to be solved by the present invention is not limited to the above-mentioned technical problems, and various technical problems can be included within the scope of what is well known to a person skilled in the art from the following description.

According to an aspect of the present invention, there is provided an authentication apparatus including a storage unit for storing user information including biometric signal information, a sensor unit for recognizing user's biometric signal information, And an NFC antenna for transmitting and receiving a radio signal to and from the NFC reader, wherein the NFC controller turns on the NFC function when the user authentication is successful, on state only when the NFC antenna is in the ON state.

Further, the authentication unit according to an embodiment of the present invention is characterized in that the sensor unit recognizes the fingerprint information with the biometric signal information of the user.

In addition, the authentication apparatus according to an embodiment of the present invention is characterized in that the sensor unit recognizes the inputted touch pattern information.

In addition, the authentication apparatus according to an embodiment of the present invention may be configured such that, when the NFC controller approaches the NFC reader within a predetermined distance from the NFC reader, the NFC antenna processes a radio signal transmitted / received with the NFC reader .

In the authentication apparatus according to an embodiment of the present invention, when the user authentication of the bio-signal information fails, the NFC controller requests additional authentication, and when the additional authentication is successful, the NFC antenna transmits / .

At this time, the authentication apparatus according to an embodiment of the present invention requests the NFC controller to perform additional authentication including any one of touch input pattern recognition, ID and password recognition, number recognition, and touch time interval recognition . In addition, the NFC controller may be configured to shut off power to be supplied to the parts when the user authentication of the bio-signal information fails.

In addition, the authentication apparatus according to an embodiment of the present invention is characterized in that the NFC controller encrypts a radio signal to transmit and receive the NFC antenna.

In addition, the authentication apparatus according to an embodiment of the present invention is characterized in that, when the NFC antenna receives a radio signal for wireless charging, it generates power and supplies power to the NFC controller.

In this case, the authentication apparatus according to an embodiment of the present invention is characterized in that the NFC antenna is a loop antenna.

In addition, the authentication apparatus according to an embodiment of the present invention further includes an auxiliary battery for generating power by energy harvesting and supplying auxiliary power. At this time, the auxiliary battery generates electric power by energy harvesting of any one of solar power generation, piezoelectric power generation, electromagnetic power generation, and thermoelectric power generation.

In addition, the authentication apparatus according to an embodiment of the present invention further includes a display unit.

According to another aspect of the present invention, there is provided a security card including a substrate, a storage unit on the substrate, a sensor unit on the substrate, an NFC control unit electrically connected to the sensor unit and the storage unit on the substrate, An NFC antenna unit electrically connected to the control unit, and a wiring formed on the substrate to electrically connect the storage unit, the sensor unit, the NFC controller, and the NFC antenna unit, wherein the NFC antenna unit and the wire One of which includes a conductive layer, the conductive layer includes a top surface, a bottom surface, and a side surface, and the conductive layer includes a resin that is a plurality of voids and a binder, Is greater than the width of the second portion.

Meanwhile, an authentication method of an authentication apparatus according to an embodiment of the present invention includes the steps of: transmitting / receiving a radio signal to / from an NFC reader by an NFC antenna unit; generating power when the NFC antenna unit receives a radio signal for wireless charging; A step in which the power is supplied to the sensor unit to activate the sensor unit, the sensor unit recognizes the user's biometric signal information, the user authentication is performed by comparing the recognized biometric signal information with the stored biometric signal information, Converting an NFC function into an on state, and processing a radio signal transmitted / received with the NFC reader.

The authentication apparatus and the authentication method of the present invention can activate the NFC function only when the user's biometric signal information is recognized and build a dual security system by tagging the NFC reader directly by the user to enhance security.

In order to solve the problem that the conventional NFC card is very vulnerable to security when renting or losing, the authentication device and the authentication method of the present invention are authenticated through the biometric signal information of the card user, .

Further, since the authentication device and the authentication method of the present invention have the characteristics of the NFC technology that can sufficiently secure matching and distance more than the magnetic effect, it is possible to provide a simple and safe service to the user can do.

1 and 2 relate to the configuration of a conventional NFC card module
Fig. 3 relates to the configuration of the authentication apparatus of the present invention.
Figure 4 relates to an embodiment of the components included in the authentication device of the present invention.
Fig. 5 relates to an embodiment of the authentication method of the authentication apparatus of the present invention.
6A and 6B are flowcharts showing an authentication method of the authentication apparatus of the present invention.

Hereinafter, the 'authentication apparatus and authentication method' according to the present invention will be described in detail with reference to the accompanying drawings. The present invention is not limited to the above-described embodiments, and various changes and modifications may be made without departing from the scope of the present invention. In addition, the matters described in the attached drawings may be different from those actually implemented by the schematic drawings to easily describe the embodiments of the present invention.

In the meantime, each constituent unit described below is only an example for implementing the present invention. Thus, in other implementations of the present invention, other components may be used without departing from the spirit and scope of the present invention.

Also, the expression " comprising " is intended to merely denote that such elements are present as an expression of " open ", and should not be understood to exclude additional elements.

Also, the expressions such as 'first, second', etc. are used only to distinguish between plural configurations, and do not limit the order or other features among the configurations.

In the description of the embodiments, it is to be understood that each layer (film), area, pattern or structure may be referred to as being "on" or "under / under" Quot; includes all that is formed directly or through another layer. The criteria for top / bottom or bottom / bottom of each layer are described with reference to the drawings.

 When a part is "connected" to another part, it includes not only "directly connected" but also "indirectly connected" with another part in between. Also, when an element is referred to as "comprising ", it means that it can include other elements, not excluding other elements unless specifically stated otherwise.

Fig. 3 relates to the configuration of the authentication apparatus of the present invention. Figure 4 also relates to an embodiment of the components included in the authentication device of the present invention.

3 and 4, the authentication apparatus 300 of the present invention includes a storage unit 310, a sensor unit 320, an NFC controller 330, an NFC antenna unit 340, an auxiliary battery 350, And an auxiliary memory 360.

At this time, the authentication device 300 of the present invention may include all general devices capable of performing the NFC function. Accordingly, the present invention can include all the general devices to which NFC communication is applied, such as a smart terminal, a credit card, a check card, a personal PDA, an ID card, a wireless payment terminal, and the security can be further enhanced by applying the present invention to these devices .

The storage unit 310 may store user information including biometric signal information. At this time, the storage unit stores user information required for user authentication such as bio-signal information, touch input pattern recognition information input by the user, user ID and password information, number information, touch time interval information, . Also, since the storage unit of the present invention must be included in the authentication apparatus 300, the storage unit of the present invention can be miniaturized / integrated in a module form on an NFC chip.

The sensor unit 320 can recognize the user's biometric signal information. At this time, the sensor unit 320 can recognize the fingerprint information using the user's biometric signal information and can recognize the inputted touch pattern information. At this time, the sensor unit of the present invention is constituted by a fingerprint recognition sensor, and can acquire image information of a user's fingerprint fingerprint, and can acquire image information of a fingerprint of a user by various methods such as optical, capacitive, electric conduction, ultrasonic, The fingerprint of the user can be acquired by the method.

Meanwhile, the sensor unit 320 may detect biometric signals such as blood flow rate, blood flow velocity, electrocardiogram, and body temperature as biometric signal information as well as fingerprints, and may use the biometric signals for user authentication.

In addition, the sensor unit includes various sensors such as a capacitance change type, a resistance change type, and a light amount change type to recognize the touch of the user as well as the fingerprint recognition, so that when the user touches, And transmits the information to the NFC controller to authenticate the user as a legitimate owner as described later.

The NFC controller 330 compares the recognized biometric signal information with the stored biometric signal information, and if the user authentication is successful, the NFC controller 330 can convert the biometric signal information into the NFC function on state. In this case, the NFC controller 330 may be implemented as one NFC chip integrated with the storage unit 310 described above, and the NFC controller and the storage unit may be implemented with different chips.

At this time, the NFC controller of the present invention processes a radio signal transmitted / received from the NFC antenna unit only when the NFC function is turned on. This is to solve the security problem that the conventional NFC module has, and is to verify the user's bio-signal information and to communicate with the external NFC reader after the comparison authentication.

More specifically, the authentication device of the present invention compares the user's biometric signal information recognized by the sensor with the stored biometric signal information to check whether the user's biometric signal information corresponds to the user or the owner of the authentication device. . After the user authentication is successful, the NFC function is activated. Therefore, when the authentication device of the present invention is rented or stolen, even if the authentication device is brought close to the NFC reader, since the user's biometric signal information is not recognized, the NFC function is not activated and the payment fails.

In addition, the NFC controller of the present invention can request additional authentication when the user authentication of the bio-signal information fails, and can process the radio signal transmitted / received by the NFC antenna when the additional authentication is successful. If the user's biometric signal information is not correctly recognized or the authentication device does not update properly according to the change of the biometric signal, the card may not be used even if it is a true user. Therefore, the use of the authentication apparatus can be made possible through the additional authentication means

More specifically, the NFC controller of the present invention can request additional authentication including any one of touch input pattern recognition, ID and password recognition, number recognition, and touch time interval recognition. The touch input pattern compares a touch input pattern and a stored touch input pattern input from the sensor unit 320 of the present invention or a separate user terminal interlocked with the authentication apparatus of the present invention to perform user authentication.

Also, it is possible to input user ID (ex) security, password (ex) 1234, and number (ex) 12345678, which are designated by the user as unique information, have. Also, it is possible to perform user authentication on the time interval pattern of touching the sensor unit 320 of the present invention. For example, when touching the sensor unit according to a certain beat by touching for 0.5 second without touching for 1 second after touching for 0.5 second, the NFC controller of the present invention processes the radio signal after confirmation with the additional authentication means do.

5, when the NFC antenna approaches the NFC reader within a predetermined distance, the NFC controller of the present invention can process a radio signal transmitted / received by the NFC antenna with the NFC reader. Because NFC technology can communicate only at close distances, it is more secure than other technologies accessible by others through hacking or radio interference from distant locations. Therefore, the NFC controller of the present invention transmits / receives radio signals when approaching within a certain distance (e.g., 10 cm).

As described above, when authentication is performed using the authentication apparatus of the present invention, the user proceeds the user authentication through the sensor unit 320 of the authentication apparatus using the fingerprint fingerprint 321 or the like. Then, the authentication apparatus of the present invention succeeds in user authentication, activates the NFC function, brings the authentication apparatus 300 closer to the NFC reader 400, and enables card use.

Meanwhile, the NFC controller of the present invention encrypts a radio signal and transmits / receives NFC antennas. In order to further enhance the security authentication, it is possible to encrypt and decrypt the wireless signal itself transmitted and received between the NFC authentication apparatus and the NFC reader, thereby making it impossible for the other terminal or module to identify the wireless signal. More specifically, when transmitting a radio signal, the NFC terminal can encrypt data using a variety of coding schemes such as Modified Miller coding and Manchester coding.

Also, since the authentication device including NFC can transmit and receive data at the same time, the entire RF field can be monitored, and it can be checked whether the received signal is matched with the transmitted signal to check whether the transmission / reception is performed properly.

 The NFC antenna unit 340 transmits and receives a radio signal to and from the NFC reader, and the NFC controller processes the radio signal transmitted and received by the NFC antenna unit when the NFC function is on. At this time, when the NFC antenna unit receives a radio signal for wireless charging, it can generate power and supply power to the NFC controller, and can be a loop antenna.

In the case of using the authentication apparatus of the present invention, even if no separate power is supplied to the NFC antenna unit 340, wireless signals can be transmitted / received only by accessing the NFC reader 400. When the authentication apparatus including the NFC antenna unit accesses the NFC reader, a magnetic field is formed between the NFC antenna unit and the antenna incorporated in the NFC reader. Here, since the magnetic field generates a current due to the electromagnetic induction phenomenon, power can be supplied to the NFC controller 330 without a separate battery.

In this case, the NFC antenna unit of the present invention may include a first NFC antenna for transmitting and receiving a radio signal to and from the NFC reader, and a second NFC antenna having a wireless charging function for supplying power to the NFC controller.

In addition, the authentication apparatus of the present invention may further include an auxiliary battery 350. [ The auxiliary battery can generate power with energy harvesting, and can supply the auxiliary power to the parts included in the authentication device. However, the auxiliary battery of the present invention may be formed as one module with the NFC antenna unit, or may be formed as different parts. In addition, the NFC antenna may be converted to an energy source using a direct energy harvesting method.

Energy harvesting is a technology that can convert electricity from natural energy sources into electricity through self-generated electricity to devices that are difficult to supply electricity. At this time, the auxiliary battery of the present invention can generate electric power by energy harvesting of any one of solar power generation, piezoelectric power generation, electromagnetic power generation, and thermoelectric power generation.

In the case of photovoltaic power generation by the photoelectric effect, when a substance such as a metal absorbs an electromagnetic wave having a wavelength shorter than a specific wavelength, electrons are emitted to generate electrons in the material and generate energy . More specifically, an n-type semiconductor and a p-type semiconductor are stacked, and electric energy is generated according to the movement of holes and electrons between semiconductors. For example, in the case of applying solar power to the authentication device of the present invention, when the auxiliary battery is exposed to a part of the authentication device and the sunlight directly reaches the auxiliary battery portion, electrons are released by the photoelectric effect, So that power can be supplied.

In the case of piezoelectric power generation by the piezoelectric effect, mechanical energy and electrical energy are transformed through a piezoelectric material. At this time, when pressure or vibration is applied to a material having piezoelectric characteristics, electricity is generated, and a piezoelectric material can be formed through an inorganic compound such as PZT (zircon titanium). For example, in the case of applying the piezoelectric power generation to the authentication apparatus of the present invention, when pressure is applied to the front and rear surfaces of the authentication apparatus through the user's finger, energy by pressure is converted into electric energy to generate electric power.

In the case of thermoelectric power generation due to the thermoelectric effect, electricity is generated by converting the temperature difference of the object into a potential difference. The electrons of a high temperature object have higher kinetic energy than the electrons of a low temperature object. When two objects are connected, high temperature electrons spread to a low temperature part, and electric potential is generated. For example, when a thermoelectric battery is used in the authentication device of the present invention, electric energy is generated due to temperature difference between the body temperature and the air when the user holds the card. Therefore, it is possible to supply electric power to the components of the authentication apparatus of the present invention.

In addition, the authentication apparatus of the present invention may further include an auxiliary memory 360. [ Unlike the storage unit 310, the auxiliary memory may include other card information of the user and other payment information so that the authentication apparatus itself can play a role of a wallet. For example, when the authentication device of the present invention is close to the NFC reader, including the card information of the company A, the card information of the company B, the card information of the company C, and the payment information of the user, , The card of the A, B, and C companies can be selected and paid for in the NFC reader.

Further, the authentication apparatus of the present invention may further include a display unit. The display unit can display information necessary for use of the authentication apparatus of the present invention such as a wireless signal transmitted to and received from the authentication apparatus of the present invention, whether a biometric signal is authenticated, confirmation of additional authentication information, NFC reader information, and the like.

6A and 6B are flowcharts showing an authentication method of the authentication apparatus of the present invention.

Referring to FIG. 6A, the authentication method of the authentication apparatus of the present invention includes the steps of recognizing the user's biometric signal information, authenticating the user by comparing the recognized biometric signal information with the stored biometric signal information, Converting an NFC function into an on state, and processing a radio signal transmitted / received with the NFC reader.

In the case of the authentication apparatus of the present invention, NFC tagging and authentication may be performed after personal identification is applied first. In this case, the user can quickly make a payment even if he or she simply approaches the vicinity of the NFC reader in the state where the identification of the individual is performed using the fingerprint or the like to the authentication device.

6B, the authentication method of the authentication apparatus of the present invention includes the steps of transmitting and receiving a radio signal to and from an NFC reader by an NFC antenna unit, generating a power when the NFC antenna unit receives a radio signal for wireless charging, A step in which the power is supplied to the sensor unit to activate the sensor unit, the sensor unit recognizes the user's biometric signal information, the user authentication is performed by comparing the recognized biometric signal information with the stored biometric signal information, Converting an NFC function into an on state, and processing a radio signal transmitted / received with the NFC reader.

In this case, unlike FIG. 6A, NFC authentication can be performed first and then individual identification can be performed. In the case of FIG. 6A, the device may be stolen or rented while the identification of the individual is proceeding. However, since the method of FIG. 6B carries out the personal authentication with the NFC reader approaching, do. In the case of FIG. 6B, the user accesses the NFC reader and the power is generated by the NFC reader and the NFC antenna. The sensor is activated by the generated electric power, and the bio-signal information recognized by the sensor is authenticated to finally process the radio signal with the NFC reader and the NFC antenna.

On the other hand, when a conductive layer such as an electrode, a wiring, or an NFC antenna layer is formed on the authentication device of the present invention, the conventional complicated photolithography process can be simplified to metal paste ink printing by forming a printed wiring line, And the merchantability can be increased. In recent electronic devices, the thickness of the device is the most sensitive problem. Therefore, when the metal paste ink printing method of the present invention is implemented, unnecessary thickness can be reduced.

Particularly, in the case of implementing an apparatus for applying double security according to the present invention, various components such as a sensor, an NFC chip, an NFC antenna, an auxiliary memory chip, a battery, and electrodes and wiring for connecting parts and components Do. At this time, the conventional FPCB is formed by using plating or copper, and there is much waste in the formation of the first conductive layer using the D / E / S method or the like. On the other hand, Metal paste ink composed of a plurality of voids and metal particles of the metal layer is used, so that there is less waste in forming the first conductive layer when using the printing process.

In addition, the printed circuit board of the present invention may include a first substrate, a first conductive layer, and may further include a first intermediate layer and a first cover layer.

A first conductive layer and various chips may be mounted on the first substrate. In this case, the first substrate may be flexible. The first substrate may be made of a material having a more curved surface than a general flexible substrate such as PET, paper, fiber, and film. Therefore, the printed circuit board of the present invention can be used for various daily life applications in which a conventional hard substrate such as a temperature sensor for patches, clothes, NFC coils and the like can not be used.

The first conductive layer may be formed on the first substrate and may transmit / receive an electrical signal. Referring to FIG. 2B, the first conductive layer is formed on the first substrate, and includes an upper surface, a lower surface, and a side surface, and has a thickness and a height. The first conductive layer may be formed as a circuit pattern on the first substrate, and the circuit pattern may be used for the NFC coil depending on the shape of the first conductive layer.

In this case, the height of the first conductive layer may be 1 to 20 μm, preferably 1 to 10 μm, more preferably 1 to 5 μm, have. At this time, if the height of the first conductive layer is 1 탆 or less, there is a disadvantage that the electrical characteristic is reduced due to the increase in resistance, and if the height of the first conductive layer is 20 탆 or more, peeling of the first conductive layer may occur.

In this case, the lower surface of the first conductive layer refers to a surface that faces one surface of the first substrate, and the upper surface of the first conductive layer refers to a surface facing the lower surface of the first conductive layer. The cross section of the first conductive layer may be a rectangular, square, or trapezoidal shape as shown in FIG. 2B. Further, the first conductive layer may include an inclined surface, and may be a curved surface including an inclined surface. Further, the side surface of the first conductive layer refers to a portion surrounding the first conductive layer, which is the remaining portion except for the lower / upper surface.

At this time, the printed circuit board of the present invention may be formed such that the bottom width of the first conductive layer is larger than the top width of the first conductive layer while the first conductive layer is formed. Therefore, since the width of the lower surface of the first conductive layer is larger, the contact surface between the first substrate and the first conductive layer becomes wider, and the adhesion between the first substrate and the first conductive layer can be improved.

In addition, the first conductive layer may include a plurality of voids, and may include a plurality of metal particles. At this time, the first conductive layer may be formed of a metal paste ink including a plurality of metal particles and a binder. Alternatively, a plurality of voids may be formed separately in the first conductive layer itself, The first conductive layer may be formed.

At this time, a plurality of voids or a plurality of metal particles included in the first conductive layer may be formed at a certain ratio. In detail, the porosity of the first conductive layer may be formed to 5% to 50%. More preferably, the porosity of the first conductive layer may be 10% to 40%. When the porosity of the first conductive layer is lower than 5%, the adhesive force may be lowered because the proportion of the organic binder binding the metal particles is reduced. When the porosity of the first conductive layer is 50% or more, The proportion of the metal is too low to lower the conductivity and the conductivity and the electrical signal transmission rate may become low.

Similarly, the composition ratio of the metal forming the first conductive layer may be formed to be 60% to 95%. When the composition ratio of the metal is 60% or less, the electrical signal transmission rate may be lowered as in the case where the porosity of the first conductive layer is high. If the composition ratio of the metal is 95% or more, the ratio of the organic binder Can be lowered.

When the first conductive layer is composed of a plurality of metal particles, the size of the metal particles may be 50 nm to 1 m. The size of the metal particles may preferably be between 50 nm and 200 nm. More preferably from 50 nm to 100 nm. Further, the plurality of metal particles may include at least one of copper (Cu), gold (Au), and silver (Ag), and various metals having good conductivity and ductility may be used. At this time, a plurality of metal particles may be sintered between metal particles after the first conductive layer is formed on the first substrate.

Meanwhile, in the printed circuit board of the present invention, the first conductive layer may further include an organic material. Such an organic material may be formed of a resin as a binder, and the organic material or the resin may be located in a gap formed in the first conductive layer. More specifically, the cavity formed in the first conductive layer may be filled with an organic material or a resin as a bonding agent.

Further, the side surface or the inclined surface of the first conductive layer of the present invention may form a constant inclination angle. In this case, the inclination angle refers to an imaginary line perpendicular to one surface of the first substrate and an acute angle formed by the side surface or the inclined surface of the first conductive layer. When the width of the bottom surface of the first conductive layer is larger than the width of the top surface of the first conductive layer, the tilted angle is naturally formed at an angle of 10 to 80 degrees. When the inclination angle is 10 degrees or less, there is a problem that the adhesion between the first substrate and the first conductive layer can not be sufficiently generated. When the inclination angle is 80 degrees or more, the area of the first conductive layer becomes excessively wide, Problems may arise.

On the other hand, the printed circuit board of the present invention is characterized in that the top surface roughness of the first conductive layer is lower than the side roughness of the first conductive layer.

Roughness refers to the roughness of the surface and is generally a measure of the roughness and smoothness of the surface of the soil particles or inverses. To obtain such surface roughness, various numerical values such as maximum height roughness (Rt), center line average roughness (Ra), and 10 point average roughness (Rz) can be measured.

The maximum height roughness (Rt) means the distance between the highest point and the lowest point. In the case of the Rt value, since the measured value may vary depending on the measurement site, it is preferable to measure a portion representative of the surface roughness and obtain an average value thereof.

The centerline average roughness (Ra) means an arithmetic average roughness, and the roughness average value in the reference length is used. Generally, the absolute values of the lengths from the centerline to the section curves of the surface are calculated as an average within the reference length.

The 10-point average roughness (Rz) means the mean distance. An arbitrary straight line parallel to the average line of the section curve is drawn from the roughness section curve, and the average value of the distance from the baseline of the highest 5 mountains And the average value of the distance from the baseline of the bone.

In the present invention, the top surface roughness of the first conductive layer is lower than that of the first conductive layer. In the case of a plurality of metal particles forming the first conductive layer, since the width of the bottom surface is wider than the width of the top surface, various metal particles are protruded to the side surface, so that the side surface roughness becomes higher.

Specifically, the roughness value may vary depending on the size of a plurality of metal particles forming the first substrate first conductive layer of the present invention. The larger the metal particle size, the greater the maximum height roughness (Rt), the center line average roughness (Ra), and the 10-point average roughness (Rz).

Therefore, the printed circuit board of the present invention is characterized in that the upper surface of the first conductive layer has an illuminance Rt value of 10 to 60 nm, an Ra value of 5 to 30 nm, and an Rz value of 320 nm or less, 1 conductive layer has an illuminance Rt of 20 to 120 nm, an Ra value of 10 to 60 nm, and an Rz value of 40 to 240 nm.

In particular, when the first conductive layer is formed by a metal paste method including a plurality of metal particles and an organic material, the upper surface and the side surface of the first conductive layer may be rough May be lower than the printed circuit board. More specifically, when the conductive layer of the printed circuit board is formed by the conventional photolithography process, the roughness of the upper surface and the side surface of the conductive layer may be lower than the roughness of the upper surface and the side surface of the first conductive layer of the present invention. This is because the process of physically / chemically removing the upper surface and the side surface of the conductive layer in the conventional process is omitted.

In addition, the printed circuit board of the present invention may use various embodiments to improve the fixing force between the first substrate and the first conductive layer, and may include i) a first intermediate layer formed between the first substrate and the first conductive layer, Or ii) the metal particles themselves may dug and bind to the first substrate.

A first intermediate layer may be formed between the first substrate and the first conductive layer, the first intermediate layer being formed of resin, which is an organic material or a bonding material. In detail, the organic material contained in the pores of the first conductive layer or the organic material or resin having the same composition as the resin may constitute the first intermediate layer to improve the bonding force between the first conductive layer and the first substrate.

Also, a first intermediate layer may be formed by adding a separate adhesive layer between the first substrate and the first conductive layer. The adhesive layer may be formed using a material different from the organic material contained in the first conductive layer, or an organic material or resin may be used. In this case, an adhesive layer is first formed on the first substrate, and then a first conductive layer is formed on the adhesive layer to bond the first conductive layer and the first substrate to secure adhesion.

Such an adhesive layer may be any commonly used adhesive material such as polyvinyl acetate, polymer solution, cyanoacrylate, bisacrylate, polymer, urea resin, etc. In addition, various methods capable of forming an adhesive layer such as an adhesive film, an adhesive liquid, and an adhesive tape can be used.

Further, a part of a plurality of metal particles between the first substrate and the first conductive layer penetrates one surface of the first substrate to fix the first substrate and the first conductive layer to the first substrate. Particularly, when the size of the metal particles is large, it is easy to dig into the first surface of the first substrate, inducing physical bonding of the particles by swarfing, raising the temperature to the softening point of the first substrate, Lt; / RTI >

In addition, the printed circuit board of the present invention may further include a first cover layer. The first cover layer may be formed on the first conductive layer or the first intermediate layer and may be formed to cover a part of the printed circuit board according to an embodiment in which the printed circuit board is used, .

In addition, the first cover layer may be formed of the same material as the first substrate, and may serve as the first substrate. More specifically, another conductive layer, an intermediate layer and a cover layer may be further formed on the first cover layer. In addition, the first cover layer may be made of an insulating material for protecting the first conductive layer and the circuit. In addition, when the first cover layer is formed of the same material as the first substrate, the first cover layer may further include a protective layer that serves as a protective layer between the first cover layer and the first conductive layer. For example, a first intermediate layer and a first conductive layer are formed on a first substrate, and a protective layer made of an insulating material or the like may be formed on the first conductive layer. Next, a first cover layer 540 made of a flexible material such as PET film, paper or fiber is formed on the protective layer, so that another conductive layer can be formed on the first cover layer.

Further, the printed circuit board of the present invention may further include a second conductive layer on the first cover layer. At this time, the second conductive layer is formed in a layer different from the first conductive layer, and forms a conductive layer of a double layer to transmit / receive electrical signals. The second conductive layer may also be formed in the same manner as the first conductive layer, and may have a thickness and a height including an upper surface / lower surface / side surface. At this time, the bottom surface of the second conductive layer may be formed to be larger than the top surface width, and the top surface roughness of the second conductive layer may be formed to be lower than the side roughness. Also, the second conductive layer may be formed as a circuit pattern on the substrate, and a circuit pattern may be used for the NFC coil depending on the shape of the conductive layer.

On the other hand, the second conductive layer may be formed of a plurality of metal particles like the first conductive layer, and may be formed with a constant porosity or metal composition ratio. Alternatively, the metal particles and the organic material may be mixed with each other at a predetermined ratio to form a metal paste.

 Further, a second intermediate layer may be formed between the second conductive layer and the first cover layer. In this case, the second intermediate layer serves to fix the first cover layer and the second conductive layer like the first intermediate layer, and may be formed of a resin as an organic material or a bonding material, or may be formed of a separate adhesive layer, May be formed in such a manner as to be caught and fixed between the first cover layers.

Further, the second conductive layer or the second intermediate layer may form the second cover layer. In this case, the second cover layer may serve as a second substrate, such as the first cover layer, or may be made of an insulating material for protecting the second conductive layer and the circuit. On the other hand, a multilayered conductive layer may be formed on the second cover layer according to the product design such as the third conductive layer, the third intermediate layer, and the third cover layer. For example, when a circuit pattern of an NFC coil is implemented, it is possible to enhance the strength of the induced electromotive force by forming a multi-layer NFC coil and effectively use it for application of wireless charging or the like.

In addition, the conductive layer of the printed circuit board of the present invention may have the shape of an NFC coil. Near field communication (NFC) is a non-contact communication technology that uses the frequency band of 13.56 MHz as one of the RFID technologies. It is a next-generation LAN technology that is attracting attention due to its relatively low security and relatively low price because of its short communication distance. Because NFC can use both data reading and writing functions, there is no need for a reader that was previously required for the use of radio frequency identification (RFID). It is similar to existing short distance communication technology such as Bluetooth but it does not need to set up connection between devices like Bluetooth.

The embodiments of the present invention described above are disclosed for the purpose of illustration, and the present invention is not limited thereto. It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit and scope of the invention.

100, 200: Conventional card
110: Conventional NFC controller
120: Conventional NFC antenna section
210: Conventional card magnetic
220: Conventional card chip
300: Authentication device
310:
320:
321: User authentication signal input
330: NFC controller
340: NFC antenna section
350: auxiliary battery
360: auxiliary memory
400: NFC reader

Claims (15)

A storage unit for storing user information including biometric signal information;
A sensor unit for recognizing the user's bio-signal information;
An NFC controller for comparing the recognized bio-signal information with the stored bio-signal information and converting the bio-signal information into an on-state when the user authentication is successful;
An NFC antenna unit transmitting and receiving a radio signal to and from the NFC reader;
Lt; / RTI >
Wherein the NFC controller processes the radio signal transmitted / received by the NFC antenna only when the NFC function is on.
The method according to claim 1,
The sensor unit includes:
An authentication device for recognizing fingerprint information using biometric signal information of a user.
The method according to claim 1,
The sensor unit includes:
An authentication device for recognizing inputted touch pattern information.
The method according to claim 1,
Wherein the NFC controller comprises:
Wherein the NFC antenna unit processes a radio signal transmitted / received with the NFC reader when the NFC antenna unit approaches the NFC reader within a predetermined distance.
The method according to claim 1,
Wherein the NFC controller comprises:
Requesting additional authentication when the user authentication of the bio-signal information fails, and processing the radio signal transmitted / received by the NFC antenna when the additional authentication is successful.
6. The method of claim 5,
Wherein the NFC controller comprises:
An authentication unit that requests additional authentication including any one of touch input pattern recognition, ID and password recognition, number recognition, and touch time interval recognition.
The method according to claim 1,
Wherein the NFC controller comprises:
And when the user authentication of the bio-signal information fails, disconnects the power supply to the component.
The method according to claim 1,
Wherein the NFC controller comprises:
And encrypts the wireless signal to cause the NFC antenna unit to transmit and receive.
The method according to claim 1,
The NFC antenna unit includes:
And generates power and supplies power to the NFC controller when receiving a wireless signal for wireless charging.
10. The method of claim 9,
The NFC antenna unit includes:
An authentication device that is a loop antenna.
The method according to claim 1,
An auxiliary battery for generating electric power by energy harvesting to supply auxiliary electric power;
Further comprising:
12. The method of claim 11,
The auxiliary battery includes:
An authentication device which generates electric power by energy harvesting of any one of solar power generation, piezoelectric power generation, electromagnetic power generation, and thermoelectric power generation.
The method according to claim 1,
A display unit;
Further comprising:
Board;
A storage unit on the substrate;
A sensor unit on the substrate;
An NFC controller electrically connected to the sensor unit and the storage unit on the substrate;
An NFC antenna unit electrically connected to the NFC controller on the substrate; And
A wire formed on the substrate for electrically connecting the storage unit, the sensor unit, the NFC controller, and the NFC antenna unit;
/ RTI >
Wherein one of the NFC antenna portion and the wiring includes a conductive layer,
Wherein the conductive layer includes an upper surface, a lower surface, and a side surface,
Wherein the conductive layer comprises a resin that is a plurality of voids and a binder,
Wherein the width of the lower surface of the conductive layer is larger than the width of the upper surface.
Transmitting and receiving a radio signal to and from an NFC reader;
Generating a power when the NFC antenna receives a radio signal for wireless charging;
A step of supplying power to the sensor unit to activate the sensor unit;
The sensor unit recognizing the user's biometric signal information;
Comparing the recognized bio-signal information with stored bio-signal information to authenticate the user;
Converting the NFC function to an on state when the user authentication is successful;
Processing a radio signal for transmitting and receiving with an NFC reader;
.

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