KR101946505B1 - Accessory having near-field communication module - Google Patents

Abstract

An accessory having an NFC function is disclosed. The accessory includes a body, an NFC tag disposed on a first side of the body, and an adhesive material disposed on a second side of the body, wherein the NFC tag includes an NFC IC. The NFC IC has a first terminal receiving a first input signal. A memory device including a first memory area for receiving a first input signal, a second memory area for receiving a second input signal, a first memory area allocated to the first terminal and a second memory area allocated to the second terminal, an RF interface And a control circuit for accessing the first memory area when the first input signal is input to the first terminal and for accessing the second memory area when the second input signal is input to the second terminal, .

Description

ACCESSORY HAVING NEAR-FIELD COMMUNICATION MODULE < RTI ID = 0.0 >

In particular, embodiments of the present invention relate to an accessory including an NFC module. In particular, when an applicable button among a plurality of buttons is pressed, an application assigned to a pressed button of the mobile device, The present invention relates to an accessory including a module.

Recently, as near field communication (NFC) technology, which is a kind of wireless communication technology, has been developed, mobile devices utilizing NFC technology are widely distributed.

An NFC tag is a readable and writable storage medium using NFC technology. It can be read and written by an NFC terminal device supporting NFC technology such as a smart phone. For example, the NFC terminal apparatus can store the message in the NFC tag and read the message stored in the NFC tag.

Korean Unexamined Patent Application Publication No. 10-2016-0016217 (Feb. Korean Unexamined Patent Application Publication No. 10-2016-0000819 (May 2015. 05)

An object of the present invention is to provide an accessory including an NFC module capable of executing only an application assigned to a pressed button among applications installed in a mobile device when a corresponding button among a plurality of buttons is pressed.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a memory device including a plurality of memory areas allocated as many as a plurality of terminals and to access only a memory area allocated to a terminal to which an input signal is input, And an NFC module with an embedded NFC IC capable of performing data storage operations and data read operations.

According to embodiments of the present invention, an accessory having an NFC function comprises a body, an NFC tag disposed on a first side of the body, and an adhesive material disposed on a second side of the body, An NFC IC includes a first terminal for receiving a first input signal, a second terminal for receiving a second input signal, a second terminal for receiving a second input signal, A radio frequency (RF) interface for transmitting and receiving an RF signal to and from the NFC device; and a controller for controlling the first input signal to be transmitted to the outside of the NFC IC as the first button is depressed When the level of the first input signal is equal to or greater than a reference level, the first address is input to the first terminal through the first button, and the first address of the first memory area is generated, Accesses a first memory area, and the second button When the second input signal is input to the second terminal via the second button disposed outside the NFC IC and the level of the second input signal is equal to or greater than the reference level, And a control circuit for generating a second address of the area and accessing the second memory area corresponding to the second address, wherein the first button is used to select the antenna and the NFC IC only when the first button is pressed And the second button electrically connects the antenna and the NFC IC only when the second button is pressed, and the RF interface rectifies the RF signal included in the reception signal transmitted from the antenna And a rectifier for generating an operating voltage of the NFC IC, wherein the operating voltage generated by the rectifier is connected to the first button and the second buzzer via a voltage output terminal of the NFC IC, And the operating voltage is supplied to the first terminal as the first input signal via the first button as the first button is depressed and the operating voltage is supplied to the first terminal as the second button is depressed, Is supplied to the second terminal as the second input signal via the second button. The first terminal and the second terminal are GPIO (general purpose input output) terminals.

According to embodiments of the present invention, an accessory having an NFC function includes a body, an NFC tag disposed on a first surface of the body, and an adhesive material disposed on a second surface of the body, An NFC IC including a first terminal, a second terminal, and a voltage output terminal, the NFC IC communicating with a near field communication (NFC) device using the antenna; A first button for supplying an output voltage to the first terminal and a second button disposed outside the NFC IC and for supplying the operating voltage output from the voltage output terminal to the second terminal, Wherein the NFC IC comprises: a rectifier for rectifying an RF signal included in a received signal transmitted from the antenna to generate the operating voltage; a first antenna terminal and a second antenna terminal; The operating voltage is supplied to the first button and the second button disposed outside the NFC IC through the voltage output terminal, and the first antenna terminal is connected to one of the two terminals of the antenna Wherein the first button comprises a first switch connected between the voltage output terminal and the first terminal and a second switch connected between the second antenna terminal and the other one of the two terminals of the antenna The second switch includes a third switch connected between the voltage output terminal and the second terminal and a fourth switch connected between the second antenna terminal and the other terminal of the antenna And when the first switch and the second switch are pressed together as the first button is depressed, the first switch switches the operating voltage generated by the rectifier And the second switch connects the second antenna terminal to the other one of the two terminals of the antenna, and as the second button is depressed, the third switch and the fourth When the switch is pressed together, the third switch supplies the operating voltage generated by the rectifier to the second terminal, and the fourth switch connects the second antenna terminal and the other one of the two terminals of the antenna To connect the terminals of

Wherein the NFC IC comprises: a memory device including a first memory area and a second memory area; and a second memory area in which the first input signal is input to the first terminal through the first button as the first button is pressed, When a level of one input signal is equal to or greater than a reference level, the first address of the first memory area is generated and the first memory area corresponding to the first address is accessed, and as the second button is pressed Generating a second address of the second memory area when the second input signal is input to the second terminal through the second button and the level of the second input signal is equal to or greater than the reference level, And a control circuit for accessing the second memory area corresponding to the address.

One integrated NFC tag according to embodiments of the present invention controls execution of each of a plurality of applications installed in a mobile device capable of performing NFC with the NFC tag by using each of the plurality of buttons implemented in the NFC tag There is an effect that can be done.

The NFC tag may be configured such that when an input signal is input through any one of GPIO terminals among GPIO terminals implemented in the NFC tag, one of the memory areas of one memory device Terminals can access only a memory area allocated to the terminal, thereby storing data in the memory area or reading data from the memory area.

The NFC IC according to the embodiment of the present invention can divide the memory area of one memory device into a plurality of memory areas by the number of GPIO terminals that can be connected to the NFC IC, It is possible to access any one of the plurality of memory areas based on the operation voltage fed back to the NFC IC through any one of the terminals. Therefore, the integration degree of the NFC tag using the NFC IC is improved.

The NFC tag having the embedded NFC IC that can be attached to the mobile device is installed in the mobile device when any one of the plurality of buttons included in the NFC tag is pressed, There is an effect of having convenience and utility that can be immediately executed.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS In order to more fully understand the drawings recited in the detailed description of the present invention, a detailed description of each drawing is provided.
1 illustrates a mobile device incorporating an accessory including an NFC module according to an embodiment of the present invention.
2 conceptually illustrates an NFC system according to embodiments of the present invention.
3 conceptually illustrates an NFC IC according to embodiments of the present invention.
4 is a view for explaining the operation of the NFC IC according to the embodiments of the present invention.
5 conceptually illustrates an NFC tag according to embodiments of the present invention.
6 conceptually illustrates an NFC tag according to embodiments of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Reference will now be made in detail to the preferred embodiments of the present invention, examples of which are illustrated in the accompanying drawings.

1 illustrates a mobile device incorporating an accessory including an NFC module according to an embodiment of the present invention. 1, an accessory 1500 including an NFC module 1000 may be adhered (or attached) to a mobile device 2000 through an adhesive material (or adhesive means) 1511. Of course, the accessory 1500 with NFC functionality can be adhered or attached to the mobile device case where the mobile device 2000 can be inserted or the mobile device 2000 can be protected from external impacts.

The accessory 1500 includes a body 1501 and an NFC module 1000 formed on a first surface 1503 of the body 1501. The body 1501 includes a body 1501, A ring connecting portion 1505 formed (or arranged) on a first surface (first surface or back surface) 1503 of the body 1501, a ring 1507 connected to the ring connecting portion 1505, (Or disposed) on the second surface or the front surface 1509 of the substrate.

(Device, part, or part) for adhering (attaching, fixing, or connecting) the accessory 1500 having the NFC function to the mobile device case in which the mobile device 2000 or the mobile device 2000 can be inserted The adhesive material 1511 may be used as an adhesive agent, an adhesive sheet, a compression plate (compression rubber or adsorbent rubber) capable of attaching the body 1501 to a mobile device or a mobile device case, or the like But is not limited thereto. 1, an accessory 1500 with a ring 1507 is shown for convenience of explanation, but the shape of the accessory 1500 can be variously modified or modified according to the designer. The accessory 1500 can be attached to or detached from the mobile device 2000 or the mobile device by the adhesive material 1511. [

The NFC module 1000 can exchange signals with an NFC transceiver installed in the mobile device 2000 using NFC technology. The NFC module 1000 may refer to an NFC tag. The possibility of the user of the mobile device 2000 dropping by using his / her fingers in the ring 1507 of the accessory 1500 is reduced. In addition, a user of the mobile device 2000 can use the ring 1507 of the accessory 1500 as a pedestal.

2 conceptually illustrates an NFC system according to embodiments of the present invention. Referring to FIGS. 1 and 2, a near field communication (NFC) system 10 may include an NFC tag 1000 and a mobile device 2000 having an NFC function. According to embodiments, the NFC system 10 may further include a host 3000. The mobile device 2000 having the NFC function means an NFC device.

NFC is one of the radio frequency identification (RFID) schemes and refers to a contactless communication technology using the frequency band of 13.56 MHz. The operating modes of the NFC may include a card emulation mode, a reader / writer mode, and a peer to peer (P2P) mode.

The card emulation mode is a mode in which an NFC apparatus having an NFC tag or an NFC IC operates as if it is an NFC tag, and the reader / writer mode is a mode in which the NFC apparatus operates as a reader for reading another NFC tag, The P2P mode is a mode for supporting link level communication between two NFC devices.

An NFC tag (or NFC module) 1000 that can be attached, disposed, formed, or coupled to the first surface 1503 of the accessory 1500 may communicate with the NFC device 2000 using an NFC scheme ). According to embodiments, the NFC apparatus 2000 may operate in a reader / writer mode and the NFC tag 1000 may operate in a card emulation mode. The accessory 1500 may be formed integrally with the mobile device case.

The NFC tag 1000 can exchange signals (e.g., radio frequency (RF) signals) with the NFC apparatus 2000. According to embodiments, the frequency of the signals transmitted between the NFC tag 1000 and the NFC device 2000 may be 13.56 MHz.

The NFC tag 1000 can transmit the transmission signal TS to the NFC apparatus 2000 and the NFC tag 1000 can receive the reception signal RS from the NFC apparatus 2000. [ The signal (TS or RS) may contain a corresponding message.

The message may refer to a resource used for communication. According to embodiments, the message may be an NDEF message. The NDFC (NFC Data Exchange Format) message is a basic message structure defined in the NFC communication protocol. NDEF is a standard exchange format for Uniform Resource Identifiers (URIs), smart posters, and others that define the record format for message exchanges between compatible devices and tags in the NFC Forum.

An NDEF message contains one or more NDEF records. An NDEF record includes a payload described by type, length, and option identifier. The NDEF payload refers to application data contained within an NDEF record.

The NFC tag 1000, which may also be referred to as an NFC module, is capable of communicating with the host 300. The NFC tag 1000 may include an NFC IC 1100, buttons 1210, 1230, 1250, and 1270, and an antenna 1300.

The NFC IC 1100 can communicate with the NFC apparatus 2000 through the antenna 1300 using the NFC scheme. The NFC IC 1100 may transmit the transmission signal TS to the NFC apparatus 2000 through the antenna 1300 and the NFC IC 1100 may transmit the reception signal RS transmitted from the NFC apparatus 2000 to the antenna 1300).

The NFC IC 1100 can receive the respective input signals IN1 to IN4 from the respective buttons 1210, 1230, 1250, and 1270. [

The NFC IC 1100 may refer to an integrated circuit (IC) formed on or above one silicon substrate. The structure and function of the NFC IC 1100 will be described in detail.

Each of the buttons 1210, 1230, 1250, and 1270 may transmit each of the input signals IN1 to IN4 to the NFC IC 1100. [ In accordance with embodiments, each of the buttons 1210, 1230, 1250, and 1270 may control the connection and disconnection of the NFC IC 1100 and the antenna 1300.

When the buttons 1210, 1230, 1250, and 1270 are pressed, the antenna 1300 and the NFC IC 1100 are electrically connected, and when the buttons 1210, 1230, 1250, and 1270 are not pressed, 1300 may be electrically isolated from the NFC IC 1000. [ Accordingly, the NFC IC 1100 can perform communication only when each button 1210, 1230, 1250, and 1270 is pressed.

Herein, the meaning that two components are connected means not only that the two components are directly electrically connected but also that there is at least one other component between the two components , Meaning that the two components are indirectly electrically connected via the at least one other component.

Each of the buttons 1210, 1230, 1250, and 1270 may be implemented as a switch such as a contact switch, a push button switch, or a touch pad switch, May refer to a configuration capable of supplying a signal (e.g., a voltage or a current) of its input terminal to its own output terminal in response to a push (or touch) operation.

Although four buttons 1210, 1230, 1250, and 1270 are shown in FIG. 2, it is for convenience of explanation that the technical idea of the present invention is applied to buttons (or buttons) The present invention is not limited thereto.

The antenna 1300 may receive the transmission signal TS output from the NFC IC 1100 and transmit the transmission signal TS to the NFC apparatus 2000. The antenna 1300 may receive the received signal RS from the NFC apparatus 2000 and may transmit the received signal RS to the NFC IC 1100. [

According to embodiments, the antenna 1300 may be electrically connected to the NFC IC 1100 or electrically connected to the NFC IC 1100, depending on the operation (e.g., depression) of the respective button 1210, 1230, 1250 and 1270 Can be separated. The connection means a state in which a signal can be transmitted between the antenna 1300 and the NFC IC 1100 and a separation means a state in which a signal can not be transmitted between the antenna 1300 and the NFC IC 1100.

The NFC apparatus 2000 may mean a device capable of communicating (that is, capable of exchanging signals) with the NFC tag 1000 by the NFC method. The NFC apparatus 2000 can receive the transmission signal TS from the NFC tag 1000 and can transmit the reception signal RS to the NFC tag 1000. [ The NFC apparatus 2000 can transmit a message to the NFC tag 1000 using the received signal RS and receive the message from the NFC tag 1000 using the transmitted signal TS.

The NFC device 2000 may be a mobile phone, a smart phone, a tablet personal computer, a mobile internet device (MID), an Internet of Things (IoT) device, a wearable computer, (NFC reader), but the present invention is not limited thereto, and may mean a device supporting NFC communication.

The NFC apparatus 2000 may execute an application 2100 stored in a medium (e.g., a memory device) of the NFC apparatus 2000. In this specification, an application refers to an application program, an application, or a mobile application program, etc., and an application performs an operation (for example, operation of exchanging data). The application uses a processor of a device on which the application is executed To perform the above operation.

For example, an application may transmit (or receive) a signal (or data) may be transmitted by a wireless communication module (e.g., a wireless transceiver) installed in a device on which the application is executed, (Or data) to and from an external wireless communication device according to the present invention. Accordingly, the operations performed by the application described herein are interpreted as operations performed by the application or the device in which the application is installed, under the control of the processor.

The application 2100 may generate a message to be sent to the NFC tag 1000. In accordance with embodiments, application 2100 may generate a message containing instructions that instruct it to perform a particular operation of NFC device 2000, and may transmit the generated message to NFC tag 1000 using the NFC scheme .

The application 2100 can receive the message transmitted from the NFC tag 1000 and control the operation of the NFC apparatus 2000 according to the command included in the message. According to the embodiments, the application 2100 may interpret the instructions contained in the message sent from the NFC tag 1000 and automatically perform the operation of the NFC apparatus 2000 indicated by the instruction.

For example, when the application 2100 receives a message including an instruction for instructing execution of a moving image application, the application 2100 can control the NFC apparatus 2000 so that the moving image application is executed according to the message.

The host apparatus 3000 that can be added to the NFC system 10 can transmit information necessary for controlling the host apparatus 3000 to the NFC apparatus 2000 through the NFC tag 1000. [ The host device 3000 may broadly refer to an electronic device that can be controlled via the NFC tag 1000. According to the embodiment, the host apparatus 3000 may be implemented as a household appliance or a healthcare apparatus.

3 conceptually illustrates an NFC IC according to embodiments of the present invention. 2 and 3, the NFC IC 1100 may include terminals 1111, 1113, 1115, and 1117, a memory device 1120, a control circuit 1130, and an RF interface 1140 And may further include a host interface 1150 according to embodiments, and may further include a voltage output terminal 1160, as shown in FIG. 4 or 5, according to embodiments. For example, terminals 1111, 1113, 1115, and 1117 may be GPIO terminals.

As shown in FIG. 5 or 6, the NFC IC 1100 may further include an output stage capacitor 1162. FIG. 5 and 6, the output stage capacitor 1162 is shown external to the NFC IC 1100A or 1100B, but according to embodiments, the output stage capacitor 1162 is provided on the inside of the NFC IC 1100A or 1100B on chip.

The GPIO terminals 1111, 1113, 1115 and 1117 are connected to a circuit (or NFC tag 1100) as general purpose input / output terminals that are included (or connected) in a control circuit 1130 )) Input and / or output functions can be performed according to the needs of the designer. Each of the GPIO terminals 1111, 1113, 1115, and 1117 can receive the corresponding analog signal (or digital signal) and output a digital signal.

The first GPIO terminal 1111 receives the first input signal IN1 and the second GPIO terminal 1113 receives the second input signal IN2 and the third GPIO terminal 1115 receives the third input signal IN3, And the fourth GPIO terminal 1117 receives the fourth input signal IN4.

Although four GPIO terminals 1111, 1113, 1115, and 1117 are illustrated in FIG. 2 for illustrative purposes, embodiments of the present invention are not limited to the number of GPIO terminals .

The memory device 1120 can store data necessary for operation of the NFC IC 1100. [ The memory device 1120 may include a non-volatile memory and / or a volatile memory.

The nonvolatile memory may be implemented as a read only memory (ROM), a flash memory, or a resistive RAM, and the volatile memory may be implemented as random access memory (RAM), static random access memory (SRAM) But is not limited thereto.

The memory device 1120 can exchange data with the control circuit 1130. In accordance with embodiments, memory device 1120 may be accessed by control circuit 1130. [ For example, control circuitry 1130 may access memory device 1120 to store data in memory device 1120 or to read data from memory device 1120.

The control circuit 1130 can control the overall operation of the NFC IC 1100. [ According to embodiments, the control circuit 1130 may control communication between the NFC IC 1100 and the NFC device 2000.

According to embodiments, the control circuitry 1130 may receive and operate an operating voltage from a power source, such as a battery, and may receive and operate the operating voltage generated by the RF interface 1140. The RF interface 1140 may include a rectifier capable of generating a DC voltage (or operating voltage) from a radio frequency (RF) signal transmitted from the NFC device 2000. The NFC tag 1100 may be implemented as a non-powered NFC tag.

The control circuit 1130 may generate a transmit message TMSG and transmit the generated transmit message TMSG to the RF interface 1140 and receive the receive message RMSG from the RF interface 1140. The transmission message (TMSG) is a message to be transmitted to the NFC apparatus 2000, and the reception message (RMSG) is a message received from the NFC apparatus 2000. Thus, the RF interface 1140 may include a modulator for converting a transmit message (TMSG) to a transmit signal (TS) and a demodulator for converting the received signal (RS) into a receive message (RMSG). The control circuit 1130 may control the operation of each of the rectifier, the modulator, and the demodulator.

As described above, the transmission message (TMSG) may include an instruction to control the NFC apparatus 2000. For example, the transmission message (TMSG) may include an instruction to instruct execution of at least one of the applications installed in the NFC apparatus 2000. The receive message (RMSG) may include an instruction to control the operation of the control circuit 1130 and may be interpreted by the control circuit 1130.

The control circuit 1130 can access the memory device 1120. According to embodiments, control circuit 1130 may read data from memory device 1120 or store data (DATA) in memory device 1120.

The RF interface 1140 may generate or receive an RF signal. The RF interface 1140 may receive the transmission message TMSG from the control circuit 1130 and generate the transmission signal TS using the transmission message TMSG. In accordance with embodiments, the RF interface 1140 may modulate a transmit message (TMSG) to generate a transmit signal (TS).

The RF interface 1140 may receive the received signal RS from the NFC device 2000 and may generate a received message RMSG using the received signal RS. According to embodiments, the RF interface 1140 may demodulate the received signal RS to generate a receive message (RMSG).

The RF interface 1140 can transmit the transmission signal TS to the antenna 1300. [ The RF interface 1140 may receive the received signal RS from the antenna 1300. In accordance with embodiments, the RF interface 1140 may include circuitry such as a bandgap reference circuit, a plurality of voltage comparators, and a Schmitt trigger.

The RF interface 1140 may further include a rectifier that rectifies the RF signal contained in the received signal RS transmitted from the antenna 1300 to generate power (or operating voltage) of the NFC tag 1100 have. The rectifier can rectify the received signal (RS) to generate an operating voltage and generate an operating voltage having a DC level.

The RF interface 1140 can transmit the operating voltage to the control circuit 1130. [ Therefore, the NFC IC 1100 can operate using the operating voltage. According to the embodiments, the RF interface 1140 can transmit the operating voltage to the voltage output terminal 1160 shown in FIG. 5 or 6.

The host interface 1150 may control (or interfere) the exchange of signals (or data) to be exchanged between the NFC tag 1000 and the host 3000. According to embodiments, the host interface 1150 may communicate with the host 3000 using a universal asynchronous receiver / transmitter (UART), an inter integrated circuit (I ² C), or a serial peripheral interface (SPI) But is not limited thereto.

The voltage output terminal 1160 can output a voltage (e.g., a voltage generated by the rectifier) to the outside of the NFC IC 1100. [ According to the embodiments, the voltage output terminal 1160 can output the voltage generated by the NFC IC 1100 to the outside. For example, the voltage output by the voltage output terminal 1160 may be a voltage generated by the RF interface 1140 of the NFC IC 1100, but is not limited thereto.

According to embodiments, the voltage output from the voltage output terminal 1160 may be a rectified voltage (e.g., a DC (direct current) voltage).

An output stage capacitor 1162 connected between the voltage output terminal 1160 and the ground may receive and store the voltage output from the voltage output terminal 1160. According to embodiments, the output stage capacitor 1162 may be a capacitor embedded in the NFC tag 1000, 1100A, or 1100B, but is not limited thereto.

According to embodiments, the NFC IC 1000 may include a CMOS oscillator. Unlike a crystal oscillator, the CMOS oscillator does not include a crystal material. Therefore, the manufacturing cost is low and the size can be reduced. The CMOS oscillator may be fabricated by a complementary metal oxide silicon (CMOS) fabrication process.

Since the NFC IC 1000 can be formed on one silicon substrate, the manufacturing process can be simplified.

4 is a view for explaining the operation of the NFC IC according to the embodiments of the present invention. Referring to Figures 2 to 4, the memory device 1120 may include memory regions REG1 to REG4.

Each of the memory areas REG1 to REG4 may be a memory area that virtually distinguishes the memory device 1120. [ For example, memory regions REG1 through REG4 may refer to memory regions of a non-volatile device included in memory device 1120. [ According to the embodiments, different data may be stored in each of the memory areas REG1 to REG4.

The size (e.g., data storage capacity) of each of the memory areas REG1 to REG4 may be different, but is not limited thereto. The size of each of the memory areas REG1 to REG4 may be set in advance.

Each of the memory regions REG1 to REG4 can be defined or divided (or distinguished) by respective addresses ADD1 to ADD4. Each of the addresses ADD1 to ADD4 denotes an identifier for defining (or distinguishing or distinguishing) each of the memory areas REG1 to REG4 or information (or a pointer) for accessing each of the memory areas REG1 to REG4. can do. For example, each of the addresses ADD1 to ADD4 may be a physical address or a virtual address.

Each of the intervals (or offsets) between the two adjacent addresses ADD1 and ADD2, ADD2 and ADD3, and ADD3 and ADD4 may denote the size of each memory region. For example, the size of the first memory area REG1 may be defined by the difference between the first address ADD1 and the second address ADD2. Therefore, each of the addresses ADD1 to ADD4 may indicate the start address of each of the memory regions REG1 to REG4.

Each of the memory areas REG1 to REG4 may be allocated (or corresponding) to each of the GPIO terminals 1111, 1113, 1115, and 1117. For example, the first memory area REG1 is assigned to the first GPIO terminal 1111, the second memory area REG2 is assigned to the second GPIO terminal 1113, and the third memory area REG3 is assigned to the third GPIO terminal 1111. [ 1115, and the fourth memory region REG1 may be allocated to the fourth GPIO terminal 1117. [

According to the embodiments, when each of the input signals IN1 to IN4 is input, the NFC IC 1100 can access only the corresponding memory region corresponding to the corresponding GPIO terminal to which the input signal is input. For example, when the first input signal IN1 is input, the first input signal IN is input through the first GPIO terminal 1111, so that the NFC IC 1100 can receive the first input signal IN1 from among the memory regions REG1 to REG4, Only the memory area REG1 can be accessed.

For example, the NFC IC 1100 stores first data in a first memory area REG1 including instructions for instructing execution of only a first application among a plurality of applications installed in the NFC apparatus 2000, The second data including an instruction for instructing execution of the second application among the plurality of applications installed in the NFC apparatus 2000 can be stored in the second memory region REG2, 2000) to execute the corresponding application from among the plurality of applications.

For example, when the first input signal IN is input to the first GPIO terminal 1111 as the first button 1210 is pressed by the user, the NFC apparatus 2000 can directly execute the first application.

The NFC IC 1100 can independently read the first data stored in the first memory area REG1 and the second data stored in the second memory area REG2, 1100) instructs the NFC apparatus 2000 to execute a first application corresponding to the first data and a second application corresponding to the second data among a plurality of applications installed in the NFC apparatus 2000 Lt; / RTI >

According to the embodiments, each of the memory areas REG1 through REG4 may not overlap each other.

Although only four memory regions REG1 to REG4 are illustrated in FIG. 4, this is for convenience of description, and embodiments according to the concept of the present invention are not limited to the number of memory regions. The sizes of the memory areas REG1 to REG4 may be the same or different from each other. For example, the number of GPIO terminals and the number of memory areas may be equal to each other. That is, one memory area is allocated per GPIO terminal, and one application per GPIO terminal can be allocated.

The control circuit 1130 may include a main control unit (MCU) 1132 and a control logic circuit 1134. An MCU 1132, which may mean a controller or a microcontroller, can control the overall operation of the NFC IC 1100. According to embodiments, the MCU 1132 may control the operation of the control logic circuit 1134. [

The MCU 1132 can transfer (or flush) each address ADD1 to ADD4 (collectively ADD) to the control logic circuit 1134 indicating each memory area REG1 to REG4. According to embodiments, address ADD may be generated by MCU 1132 and may be read by MCU 1132 from memory contained within MCU 1132 (e.g., L1 cache or L2 cache) have.

MCU 1132 monitors the voltage (or input voltage) of each GPIO terminal 1111, 1113, 1115, and 1117 or a change in the voltage and generates an address ADD based on the result of the monitor , And send the generated address (ADD) to the control logic circuit 1134.

According to the embodiments, the MCU 1132 receives the input signals IN1 to IN4 (or the levels of the voltages of the respective input signals IN1 to IN4) input to the GPIO terminals 1111, 1113, 1115, and 1117 And generates an address ADD of a memory area corresponding to a GPIO terminal to which a corresponding input signal from the GPIO terminals 1111, 1113, 1115, and 1117 is input, and transmits the generated address ADD to the control logic circuit 1134.

For example, when the first input signal IN1 having a high level (or changing from a low level to a high level) is input to the first GPIO terminal 1111, the MCU 1132 outputs the first input signal IN1 1 input signal IN1 and generates a first address ADD1 of the first memory area REG1 corresponding to (or assigned to) the first GPIO terminal 1111 in accordance with the detection result, The first address ADD1 may be transferred to the control logic circuit 1134. [

According to the embodiments, the MCU 1132 monitors the level (or level change) of each of the input signals IN1 to IN4 input to the respective GPIO terminals 1111, 1113, 1115, and 1117, (ADD) of a memory area corresponding to a GPIO terminal to which an input signal having a large level is input, and can transmit it to the control logic circuit 1134.

For example, when the first input signal IN1 having a level higher than the reference level is input to the first GPIO terminal 1111, the MCU 1132 outputs the first input signal IN1 of the first memory region REG1 corresponding to the first GPIO terminal 1111 1 address ADD1 and may transmit the first address ADD1 to the control logic circuit 1134. [

The control logic circuit 1134 may define a protocol used in the NFC IC 1100. According to embodiments, the control logic circuit 1134 may define a card emulation mode and a peer to peer (P2P) mode according to the ISO / IEC 18092 NFC interface protocol (IP) -1 standard. The P2P mode includes an initiator mode and a target mode.

The control logic circuit 1134 may perform the function of a memory controller capable of accessing the memory device 1120. Control logic circuitry 1134 may access memory device 1120 to store data in memory device 1120 or access memory device 1120 to read data from memory device 1120 have.

According to embodiments, control logic circuit 1134 may read data (DATA) from memory device 1120 and generate (e.g., encode) a transmit message (TMSG) using the read data have. The control logic circuit 1134 may send a transmit message (TMSG) to the RF interface 1140.

According to embodiments, the control logic circuit 1134 may receive and store the received message (RMSG) sent from the RF interface 1140 in the memory device 1120. For example, the control logic circuit 1134 may receive and decode the received message (RMSG), generate data (DATA) according to the decoding result, and store the generated data (DATA) in the memory device 1120.

The control logic circuit 1134 can access any one of the memory areas REG1 to REG4 of the memory device 1120 using the address ADD sent from the MCU 1132. [ In accordance with embodiments, control logic circuit 1134 receives address (ADD, e.g., ADD1, ADD2, ADD3, and ADD4) and selects one of memory areas (REG1 to REG4) (Any one of REG1, REG2, REG3, and REG4) indicated (or identified) by the memory areas REG1, REG2, REG3, and REG4), or may store data in the memory areas REG1, REG2, REG3, and REG4.

For example, when the address ADD transmitted from the MCU 1132 is the first address ADD1, the control logic circuit 1134 can access the first memory area REG1 corresponding to the first address ADD1 have. The access may include a data storage operation for the first memory area REG1 and / or a data read operation.

The control logic circuit 1134 receives the received message (RMSG) from the RF interface 1140 (or the received message (or received message) from the RF interface 1140, (Data included in the RMSG) in the first memory area REG1 corresponding to the first address ADD1. For example, the first address ADD1 may include the start address of the first memory area REG1. The received message (RMSG) may include information related to an application installed in the NFC apparatus 2000.

For example, when the first input signal IN1 is input to the first GPIO terminal 1111, the control logic circuit 1134 outputs a receive message (RMSG) to the first memory area REG1 using the first address ADD1, And the control logic circuit 1134 stores the received message in the second memory area REG2 using the second address ADD2 when the second input signal IN2 is input to the second GPIO terminal 1113 RMSG).

During the data read operation, when the address ADD transmitted from the MCU 1132 is the first address ADD1, the control logic circuit 1134 outputs, from the first memory area REG1 corresponding to the first address ADD1, Data can be read and a transmission message TMSG can be generated using the data read from the first memory area REG1 and the transmission message TMSG can be transmitted to the RF interface 1140. [

For example, when the first input signal IN1 is input to the first GPIO terminal 1111, the control logic circuit 1134 outputs the first data stored in the first memory area REG1 using the first address ADD1 Control logic circuit 1134 can generate a first transmission message using the first data and the second input signal IN2 when the second input signal IN2 is input to the second GPIO terminal 1113. [ ADD2 to read the second data stored in the second memory area REG2 and generate the second transmission message using the second data.

The control logic 1134 uses the address ADD sent from the MCU 1132 to control the input (or output) of the memory device 1120, which is indicated (or selected) by the address ADD in the memory areas REG1- Only the memory area corresponding to the GPIO terminal to which the signal is input can be accessed.

In the storage step, the NFC IC 1100 transmits the first data including the instruction for instructing execution of the first application of the NFC apparatus 2000 to the first memory area REG1 when the first input signal IN1 is input, And the second data including the instruction for instructing execution of the second application of the NFC apparatus 2000 when the second input signal IN2 is input can be stored in the second memory region REG2, One integrated NFC IC 1100 including the buttons 1210, 1230, 1250, and 1270 of the NFC apparatus 2000 stores an instruction for instructing execution of a corresponding application among a plurality of applications executed in the NFC apparatus 2000 .

In the application execution stage, when the first input signal IN1 is input, the NFC IC 1100 reads the first data related to the execution of the first application stored in the first memory region REG1, The NFC IC 1100 of one integral type can be executed in the NFC apparatus 2000 because the second data stored in the second memory area REG2 and read out the second data related to the execution of the second application can be read To the NFC apparatus 2000, an instruction that instructs execution of the corresponding application from the plurality of applications.

The integrated NFC IC 1100 may divide the memory area of one memory device 1120 into a plurality of memory areas allocated to the GPIO terminals, and when the corresponding button is pressed, It is possible to improve the integration degree of the NFC IC 1100.

For example, although N NFC ICs are conventionally required to execute each of N (N is a natural number of 2 or more) applications, the NFC IC 1100 of the present invention can allocate memory areas of one memory device 1120 to N It is possible to use the NFC IC 1100 alone to control the execution of each of the N applications because the N memory ICs can be divided into N memory areas for execution of each of the applications.

That is, in the NFC tag 1000 of the present invention, applications corresponding to the number of GPIO terminals can be individually executed. One NFC IC 1100 can control the execution of each of the N applications.

5 conceptually illustrates an NFC tag according to embodiments of the present invention. Referring to FIG. 5, an NFC tag 1000A according to an embodiment of the NFC module 1000 or the NFC tag 1000 of FIG. 2 includes an NFC IC 1100A, buttons 1210A, 1230A, 1250A, and 1270A, And an antenna 1300A. The NFC tags 1000, 1000A, or 1000B described herein may provide an RF interface 1140 to allow RF communication between the NFC device 2000 and the host 3000. [

The structure and function of the NFC IC 1100A of FIG. 5 are the same as or similar to the structure and function of the NFC IC 1000 shown in FIG. 3, and the structure and function of the antenna 1300A of FIG. The structure and function of antenna 1300 are the same or similar. The antenna 1300 or 1300A may be disposed on a PCB (printed circuit board) substrate having a multilayer structure.

Each button 1210A, 1230A, 1250A, and 1270A may include a respective switch P11, P21, P31, and P41. Each of the buttons 1210A, 1230A, 1250A, and 1270A can supply the operating voltage VDD output from the voltage output terminal 1160 to each of the GPIO terminals 1111, 1113, 1115, and 1117.

One terminal of each of the switches P11, P21, P31 and P41 is connected to the voltage output terminal 1160 and the other terminal of each of the switches P11, P21, P31 and P41 is connected to each of the input signals IN1 to IN4 1113, 1115, and 1117, respectively, to which the GPIO terminals 1111, 1113, 1115, and 1117 transmit signals. Each of the switches P11, P21, P31, and P41 may be formed of a MOSFET using a CMOS process.

As the buttons 1210A, 1230A, 1250A, and 1270A are pressed, the operating voltage VDD can be supplied to the corresponding GPIO terminals 1111, 1113, 1115, and 1117 as corresponding input signals IN1 to IN4 have. For example, when the first button 1210A is pressed, the first switch P11 is also pressed, and the voltage output terminal 1160 and the first GPIO terminal 1111 are connected with each other as the first switch P11 is pressed, The voltage VDD may be supplied to the first GPIO terminal 1111 through the first button 1210A. The first button 1210A may supply the operating voltage VDD to the first GPIO terminal 1111 as the first input signal IN1.

As described above, as the first button 1210A is pressed, the NFC tag 1000A accesses the first memory area REG1 (e.g., the memory area allocated to the first GPIO terminal 1111) The NFC tag 1000A accesses the second memory area REG2 (e.g., the memory area allocated to the second GPIO terminal 1113) as the first button 1230A is pressed, and as the third button 1250A is pressed As the fourth button 1270A is pressed, the NFC tag 1000A accesses the third memory area REG3 (e.g., the memory area allocated to the third GPIO terminal 1115), and the NFC tag 1000A accesses the fourth It is possible to access the memory area REG4, for example, the memory area allocated to the fourth GPIO terminal 1117. [

The NFC tag 1000A is configured so that each of the buttons 1210A, 1230A, 1250A, and 1270A is selected based on each of the input signals IN1 to IN4 input as the buttons 1210A, 1230A, 1250A, and 1270A are pressed, 1230A, 1250A, and 1270A (corresponding to the GPIO terminals 1111, 1113, 1115, and 1117) corresponding to the respective memory areas REG1 to REG4 The data DATA can be read from each of the memory areas REG1 to REG4 corresponding to the corresponding GPIO terminals 1111, 1113, 1115, and 1117. [

Therefore, one integrated NFC tag 1000A can divide the memory area of one memory device 1120 into a plurality of memory areas and use it to operate each of the buttons 1210A, 1230A, 1250A, and 1270A The plurality of memory areas can be selectively accessed, so that the integration degree of the NFC device including the NFC tag 1000A can be improved.

6 conceptually illustrates an NFC tag according to embodiments of the present invention. Referring to FIG. 6, an NFC tag 1000B according to an embodiment of the NFC tag 1000 of FIG. 2 includes an NFC IC 1100B, buttons 1210B, 1230B, 1250B, and 1270B, and an antenna 1300B. .

The NFC IC 1100B of FIG. 6 is the same as or similar to the NFC IC 1100A shown in FIG. 5 except for the antenna terminals 1171 and 1173, and the function of the antenna 1300B of FIG. Which is similar or similar to the function of the antenna 1300B.

The NFC IC 1100B may include a first antenna terminal 1171 and a second antenna terminal 1173. The first antenna terminal 1171 may be connected to the first terminal 1310B of the antenna 1300B.

Each of the buttons 1210B, 1230B, 1250B, and 1270B may include respective switches P11, P21, P31, and P41 and respective switches P12, P22, P32, and P42. Each of the buttons 1210B, 1230B, 1250B, and 1270B can supply an operation voltage VDD to each of the GPIO terminals 1111, 1113, 1115, and 1117.

According to the embodiments, one terminal of each of the first switches P11, P21, P31 and P41 is connected to the voltage output terminal 1160 and the other of the first switches P11, P21, P31 and P41 Side terminals may be connected to the respective GPIO terminals 1111, 1113, 1115, and 1117. [

As each of the buttons 1210B, 1230B, 1250B and 1270B is pressed, the operating voltage VDD can be supplied to each of the GPIO terminals 1111, 1113, 1115, and 1117 as respective input signals IN1 to IN4 have. For example, when the first button 1210B is pressed, the first switch P11 of the first button 1210B is also pressed, and when the first switch P11 is pressed, the voltage output terminal 1160 and the first GPIO terminal 1111 are electrically connected to each other, the operating voltage VDD can be supplied to the first GPIO terminal 1111. That is, the first button 1210B may supply the operating voltage VDD to the first GPIO terminal 1111 as the first input signal IN1.

Each of the buttons 1210B, 1230B, 1250B, and 1270B can connect the NFC IC 1100B and the antenna 1300B. Each of the buttons 1210B, 1230B, 1250B and 1270B may electrically connect the second terminal 1320B of the antenna 1300B and the second antenna terminal 1173 of the NFC IC 1100B to each other .

One terminal of each of the second switches P12, P22, P32 and P42 is connected to the second terminal 1320B of the antenna 1300B and the other terminal of the second switches P12, P22, P32, And P42 may be electrically connected to the second antenna terminal 1173 of the NFC IC 1100B.

As each button 1210B, 1230B, 1250B, and 1270B is pressed, the NFC IC 1100B and the antenna 1300B can be connected.

For example, when the first button 1210B is pressed, the second switch P12 of the first button 1210B is also pressed, and when the second switch P12 is pressed, the second terminal 1320B of the antenna 1300B, And the second antenna terminal 1173 of the NFC IC 1100B are electrically connected to each other, so that the NFC IC 1100B and the antenna 1300B can be connected. That is, the NFC IC 1100B can communicate with the NFC apparatus 2000 using the antenna 1300B only when the first button 1210B is pressed. That is, when the first button 1210B is pressed, the switches P11 and P12 are pressed together.

The antenna 1300B and the NFC IC 1100B are electrically connected to each other when the first button 1210B is pressed and the NFC tag 1000B is electrically connected to the first memory area REG1 or the memory allocated to the first GPIO terminal 1111 Area) can be accessed. The operation when the remaining buttons 1230B, 1250B, and 1270B are pressed is the same as the operation when the first button 1210B is pressed, so that the operation of the remaining buttons 1230B, 1250B, A detailed description thereof will be omitted. When each button 1210B, 1230B, 1250B, or 1270B is pressed, the switches P11 and P12, P21 and P22, P31 and P32, or P41 and P42 are pressed together or simultaneously.

When the first button 1210B is pressed, the operation voltage VDD is supplied as the first input signal IN1 to the first GPIO terminal 1111, and at the same time, the antenna 1300B forms a closed loop.

During the data storage operation, when the first button 1210B is pressed, the NFC tag 1000B receives the RF signal from the NFC apparatus 2000 using the antenna 1300B, and outputs the data corresponding to the received RF signal 1 button 1210B, for example, the first GPIO terminal 1111 in the memory area REG1.

During the data read operation, when the first button 1210B is pressed, the NFC tag 1000B reads data stored in the memory area REG1 corresponding to the first button 1210B, for example, the first GPIO terminal 1111, Converts the read data into an RF signal, and transmits the converted RF signal to the NFC apparatus 2000 using the antenna 1300B.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is evident that many alternatives, modifications and variations will be apparent to those skilled in the art. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

10: NFC system
100: Smartphone case
1000, 1000A, 1000B: NFC tag
1100, 1100A, 1100B: NFC IC
1210, 1230, 1250, 1270, 1210A, 1230A, 1250A, 1270A, 1210B, 1230B, 1250B,
1300, 1300A, 1300B: antenna
1400: Case body
2000: NFC terminal device
2100: Application
3000: Host
P11, P21, P31, P41, P12, P22, P32, P42: Switch

Claims (10)

body;
An NFC tag disposed on a first side of the body; And
And an adhesive material disposed on a second side of the body,
The NFC tag includes:
antenna;
A first button;
A second button; And
Including NFC ICs,
In the NFC IC,
A first terminal for receiving a first input signal;
A second terminal for receiving a second input signal;
A memory device including a first memory area and a second memory area;
An RF (radio frequency) interface for exchanging RF signals with an NFC device; And
Wherein the first input signal is input to the first terminal via the first button disposed outside the NFC IC as the first button is pressed and the level of the first input signal is equal to or greater than a reference level The first address of the first memory area is generated and the first memory area corresponding to the first address is accessed, and as the second button is pressed, the second input signal is supplied to the outside of the NFC IC Generating a second address of the second memory area when the level of the second input signal is equal to or greater than the reference level and is input to the second terminal through the second button; And a control circuit for accessing the second memory area,
The first button electrically connects the antenna and the NFC IC only when the first button is pressed,
The second button electrically connects the antenna and the NFC IC only when the second button is pressed,
Wherein the RF interface includes a rectifier for rectifying an RF signal included in a reception signal transmitted from the antenna to generate an operating voltage of the NFC IC,
The operating voltage generated by the rectifier is supplied to the first button and the second button through a voltage output terminal of the NFC IC,
As the first button is pressed, the operating voltage is supplied to the first terminal as the first input signal through the first button. As the second button is pressed, the operating voltage is supplied to the second button To the second terminal as the second input signal. The method according to claim 1,
The RF interface generates a message using the RF signal transmitted from the NFC apparatus, transmits the message to the control circuit,
The control circuit comprising:
When the first input signal corresponding to the operating voltage generated by the rectifier is input to the first terminal in response to the pressing of the first button disposed outside the NFC IC, And stores it in the first memory area,
When the second input signal corresponding to the operating voltage generated by the rectifier is input to the second terminal in response to the pressing of the second button disposed outside the NFC IC, And stores the NFC function in the second memory area. 2. The control circuit according to claim 1,
The first input signal corresponding to the operating voltage generated by the rectifier is supplied to the NFC IC in response to the depression of the first button disposed outside the NFC IC Read from the first memory area using the first address when input to the first terminal, generate a first transmission message using data read from the first memory area,
When the second input signal corresponding to the operating voltage generated by the rectifier is input to the second terminal in response to the pressing of the second button disposed outside the NFC IC, Read the data from the second memory area, generate a second transmission message using the data read from the second memory area,
Wherein the RF interface has an NFC function for generating a transmission signal using the first transmission message or the second transmission message. The method according to claim 1,
The control circuit comprising:
When the first input signal corresponding to the operating voltage generated by the rectifier is input to the first terminal as the first button disposed outside the NFC IC is pressed, And the second input signal corresponding to the operating voltage generated by the rectifier is supplied to the second terminal as the second button disposed outside the NFC IC is depressed, A micro control unit for generating the second address for accessing the second memory area when inputted; And
And a control logic circuit that accesses the first memory area using the first address and accesses the second memory area using the second address. The method according to claim 1,
When the first input signal corresponding to the operating voltage generated by the rectifier is input to the first terminal as the first button disposed outside the NFC IC is pressed, Storing, in the first memory area, first data including an instruction instructing execution of a first application of the NFC apparatus,
When the second input signal corresponding to the operating voltage generated by the rectifier is input to the second terminal as the second button disposed outside the NFC IC is pressed, And an instruction for instructing execution of a second application of the NFC apparatus is stored in the second memory area. The method according to claim 1,
Wherein the first terminal and the second terminal have an NFC function that is GPIO (general purpose input output) terminals. body;
An NFC tag disposed on a first side of the body; And
And an adhesive material disposed on a second side of the body,
The NFC tag includes:
antenna;
An NFC IC including a first terminal, a second terminal, and a voltage output terminal, the NFC IC communicating with a near field communication (NFC) device using the antenna;
A first button disposed outside the NFC IC and supplying an operating voltage output from the voltage output terminal to the first terminal; And
And a second button disposed outside the NFC IC and supplying the operating voltage output from the voltage output terminal to the second terminal,
In the NFC IC,
A rectifier for rectifying an RF signal included in a received signal transmitted from the antenna to generate the operating voltage; And
A first antenna terminal and a second antenna terminal,
The operating voltage generated by the rectifier is supplied to the first button and the second button disposed outside the NFC IC via the voltage output terminal,
The first antenna terminal is connected to one of two terminals of the antenna,
Wherein the first button comprises:
A first switch connected between the voltage output terminal and the first terminal; And
And a second switch connected between the second antenna terminal and the other one of the two terminals of the antenna,
The second button
A third switch connected between the voltage output terminal and the second terminal; And
And a fourth switch connected between the second antenna terminal and the other one of the two terminals of the antenna,
When the first switch and the second switch are pressed together as the first button is depressed, the first switch supplies the operating voltage generated by the rectifier to the first terminal, and at the same time, Connects the second antenna terminal to the other one of the two terminals of the antenna,
When the third switch and the fourth switch are pressed together as the second button is pressed, the third switch supplies the operating voltage generated by the rectifier to the second terminal, and at the same time, Has an NFC function for connecting the second antenna terminal to the other one of the two terminals of the antenna. delete 8. The method of claim 7,
In the NFC IC,
A memory device including a first memory area and a second memory area; And
When a first input signal is input to the first terminal through the first button and the level of the first input signal is equal to or greater than a reference level as the first button is depressed, Address and accesses the first memory area corresponding to the first address, and as the second button is pressed, a second input signal is input to the second terminal via the second button, and the second And a control circuit for generating a second address of the second memory area when the level of the input signal is equal to or greater than the reference level and accessing the second memory area corresponding to the second address, . delete

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