KR102084195B1 - Light emitting accessory using nfc induction - Google Patents

Abstract

The present invention relates to a light emitting accessory for a mobile phone driven by NFC induction power, comprising: a substrate forming a body of an accessory; a power unit disposed on the substrate, receiving search radio waves emitted from an NFC antenna of a smartphone, and converting the search radio waves into power; a tag unit replying a response signal to the NFC antenna so that the NFC antenna continuously emits the search radio waves; and a light emitting unit receiving the power from the power unit and emitting light.

Description

Lighting accessories for mobile phones powered by NFC induction power {LIGHT EMITTING ACCESSORY USING NFC INDUCTION}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a light emitting accessory for a mobile phone, and more particularly, to a light emitting accessory using NFC induced power as driving power.

By embedding NFC chip with short range wireless communication function in mobile phone, mobile phone is developing various functions such as card payment and bus fare payment using NFC.

NFC chip can perform short-range wireless communication through the NFC antenna built into the mobile phone.

On the other hand, the apparatus like patent document 1 was disclosed focusing on the power transmission function which NFC search electric wave has.

However, according to the configuration of Patent Document 1, only the simple light emitting of the LED element is made, there is a disadvantage that does not deliver a variety of information generated in the smartphone.

Patent Document 1: Republic of Korea Patent Publication No. 10-1322205 Publication Date October 28, 2013

The present invention seeks to provide a light emitting accessory for a mobile phone using NFC induced power as the driving power.

A light emitting accessory for a mobile phone driven by NFC induction power for realizing the object of the present invention, the substrate constituting the body of the accessory; A power unit disposed on the substrate and receiving a search wave emitted from the NFC antenna of the smartphone and converting the search wave into electric power; a tag unit returning a response signal to the NFC antenna so that the NFC antenna continuously emits the search wave; And a light emitting unit which receives power from the power unit and emits light.

In this case, the power unit may include: a first antenna that receives the search radio wave and converts the power into power; And a rectifying element converting the power received from the first antenna into direct current.

The tag unit may include: a second antenna that receives the search radio wave and returns the response signal; And a tag chip for applying the response signal to the second antenna.

The tag chip may include a search propagation request code so that the NFC antenna continuously emits the search radio waves.

On the other hand, the light emitting unit, a plurality of LED elements; And it may include a control element for controlling the light emission order of the plurality of LED elements.

In addition, the plurality of LED elements may be arranged in a matrix form, and the control element may control a light emission order of each LED element such that the matrix emits light in a predetermined form.

According to the light emitting accessory for a mobile phone driven by NFC induction power according to the present invention,

First, since the power is supplied through the search radio of NFC provided in the smart phone, it is possible to exclude the mounting of the battery can be manufactured in a compact and slim form.

Secondly, since the tag unit returns a response signal so that NFC emits search waves continuously, sufficient power can be supplied to enable light emission of a plurality of LED elements.

Third, therefore, it is possible to control the light emission of a plurality of LED elements to display characters.

1 is a block diagram of a light emitting accessory for a mobile phone driven with NFC induction power according to the present invention.
FIG. 2 shows an example of driving a light emitting accessory for a mobile phone of FIG. 1.
3 is a flowchart illustrating a control process of a light emitting pattern of an LED device.
4 illustrates a light emitting accessory for a mobile phone according to another embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of the present invention. In this case, the same components in the accompanying drawings are to be noted with the same reference numerals as possible. In addition, detailed descriptions of well-known functions and configurations that may blur the gist of the present invention will be omitted. For the same reason, in the accompanying drawings, some components are exaggerated, omitted or schematically illustrated.

1 is a block diagram of a light emitting accessory for a mobile phone driven by NFC induction power according to the present invention, Figure 2 shows a driving example of the light emitting accessory for a mobile phone of FIG.

1 and 2, the light emitting accessory 1000 for a mobile phone according to the present invention includes a substrate 100, a power unit 200, a tag unit 300, and a light emitting unit 400.

The substrate 100 is a part constituting the body of the accessory 1000 and may be formed of a synthetic resin material. According to FIG. 2, the substrate 100 has a circular shape, but this is only one of the possible embodiments, and the appearance of the substrate 100 may be variously performed according to the operator.

The substrate 100 is preferably made of a printed circuit board (PCB) to enable easy placement of the power unit 200 and the light emitting unit 400.

The power unit 200 is disposed on the substrate 100 and receives the search wave emitted from the NFC antenna of the smartphone and converts it into electric power.

The power unit 200 includes a first antenna 210 and a rectifier 220.

The first antenna 210 receives the search wave emitted from the NFC antenna (NFC) and converts it to power. The first antenna 210 is preferably formed in the form of a circular coil, and may be formed of a wiring type (ie, a substrate integrated type) formed on the substrate 100 for convenience of manufacturing.

The rectifier 220 converts the electric power received and induced by the first antenna 210 into direct current so that the LED element can be driven.

According to the practitioner, the rectifier 220 may be simply implemented to include only the rectifying element, or may be implemented to further include an impedance matching circuit for efficient power conversion.

Although not shown, the rectifier 220 may further include a device for storing the power converted into direct current. The power storage element may be, for example, a capacitor or a small battery.

Since the smartphone (S) with NFC is driven by a battery, in order to minimize the power consumption, the search radio radiates at regular time intervals.

The tag unit 300 returns a response signal to the NFC antenna so that the NFC antenna (NFC) emits search waves continuously.

The tag unit 300 includes a second antenna 310 and a tag chip 320. The second antenna 310 receives the search radio wave emitted from the NFC antenna and returns a response signal based on the information stored in the tag chip 320.

The tag chip 320 controls a signal applied to the second antenna 310 so that the second antenna 310 returns a response signal.

The tag chip 320 may be implemented to include a search propagation re-request code such that the NFC antenna (NFC) emits search propagation continuously.

The smartphone S controls the NFC antenna NFC so that the NFC antenna NFC continuously emits search waves according to the response signal. That is, the smartphone S controls the NFC antenna NFC to be continuously driven by the search propagation re-request code included in the response signal.

At this time, the search propagation re-request code may include a code (app execution code) for calling a specific application in the smartphone (S).

Here, the specific application is to implement a function to control the search radio waves emitted from the NFC antenna (NFC), a dedicated application for controlling the light emitting accessory for a mobile phone 1000 to be driven in the form desired by the user.

When the smartphone S receives the app execution code, a dedicated application installed in the smartphone S is driven, and the dedicated application controls to continuously search for radio waves emitted from the NFC antenna NFC.

Therefore, the power unit 200 may receive power capable of continuously driving the light emitting unit.

The light emitting unit 400 receives power from the power unit 200 and emits light. According to an embodiment, the light emitting unit 400 includes an LED element 410 and a control element 420.

A plurality of LED elements 410 are disposed on the substrate 100. Specifically, it is disposed on the front surface 110 of the substrate 100. In the present invention, the surface that the substrate 100 is in contact with the NFC placement surface (that is, the rear of the mobile terminal) of the smartphone (S) will be referred to as the 'back', and the opposite side will be referred to as the 'front'.

Since the LED device 410 is provided to display the light emitting state to the user, the LED device 410 should be disposed on the front side of the smart phone S, not the NFC placement surface (back side).

The control element 420 controls the light emission order of each LED element 410. The control element 420 is disposed between the rectifying unit 220 and the LED element 110, and controls the power applied to each LED element 110, thereby sequentially flashing the LED element 110, a plurality of LED elements are Allows you to create a specific shape. According to the practitioner, a specific shape may be produced by using the LED elements 410 of different colors.

4 illustrates a light emitting accessory for a mobile phone according to another embodiment of the present invention.

4 illustrates an embodiment in which a plurality of LED elements 410 'are arranged in a matrix form, and the control element 420' controls the light emission order of each LED element 410 'such that the matrix emits light in a predetermined form. . According to an embodiment, a matrix having a resolution capable of displaying characters, such as an 8x8 array or a 16x16 array, may be selected.

Meanwhile, the control element 420 'receives the text to be displayed on the LED element 410' from a dedicated application driven in the smartphone S, and the received text of the LED element 410 'is sequentially displayed. Light emission can be controlled.

For example, if the user inputs 'HELLO WORLD!' To the dedicated application, the control element 420 'receives the corresponding text' HELLO WORLD! 'From the smartphone S and transmits the text to the LED element 410'. You can control that "HELLO WORLD!" Is displayed sequentially.

In this case, although the control element 420 'may control the LED element 410' to sequentially emit the light after receiving the entire text at once, a dedicated application may be used to simplify the configuration of the control element 420 '. May be implemented in such a manner that only one byte of information is transmitted to the control element 420 'at a time.

A difference in power transmission efficiency due to search propagation occurs depending on the distance between the NFC antenna NFC and the light emitting accessory 1000 for a mobile phone. For example, when the NFC antenna (NFC) and the light emitting accessory 1000 for a mobile phone are in close contact, that is, when the NFC antenna (NFC) and the first antenna 210 are in close contact with each other, the power transmission efficiency is excellent. If the NFC antenna (NFC) and the first antenna 210 are not in the right position to face, or not in close contact due to the thickness of the protective case of the smartphone (S) power transmission efficiency is low.

According to the present invention, even when the NFC antenna (NFC) and the first antenna 210 are in close contact with each other and the power transmission efficiency is high, the NFC antenna (NFC) emits search waves at maximum output to prevent waste of the battery. Provide configuration.

The dedicated application calculates the power transmission efficiency based on the strength of the response signal (i.e., search propagation request code and app execution code) returned from the tag unit 300, for example, a received signal strength indicator (RSSI) value. do.

The dedicated application scales the search propagation based on the calculated power transfer efficiency.

That is, when it is determined that the NFC antenna (NFC) and the light emitting accessory 1000 for the mobile phone are in close contact with each other, the optimal power required for driving the light emitting unit 400 may be transmitted to minimize battery loss of the smartphone S. Can be.

3 is a flowchart illustrating a control process of a light emitting pattern of an LED device. Since the light emitting accessory 1000 for the mobile phone of FIG. 1 is implemented in time series, the parts described for the substrate 100, the power unit 200, the tag unit 300, and the light emitting unit 400 remain intact in the present embodiment. Apply.

First, when the user operates the smartphone S to set the NFC to a use state, the smartphone S drives the NFC antenna NFC to transmit a search radio wave to find an RFID tag at predetermined time intervals.

In step S100, the light emitting accessory 1000 for the mobile phone receives the search radio wave. In detail, the power unit 200 and the tag unit 300 receive search radio waves.

In step S200, the tag unit 300 receives the search wave and returns a response signal accordingly.

The tag chip 320 includes a search propagation re-request code for the NFC antenna to emit search radio continuously. In addition, the tag chip 320 may further include text to be displayed on the LED device 410 ′ arranged in a matrix form.

For example, the search propagation re-request code may include a command to run a dedicated application installed in the smartphone S. Here, the dedicated application refers to an application that can operate the NFC provided in the mobile terminal according to the user's intention in order to control the light emitting accessory 1000 for the mobile phone.

For example, the smartphone S receives a search propagation re-request code to drive a dedicated application (step S300), and the dedicated application continuously controls the NFC provided in the mobile terminal to send search radio waves (step S400). Can be implemented.

The power unit 200 receives the search radio transmitted continuously and converts the power to sufficient power to drive the light emitting unit 400.

In operation S500, the control element 420 receives the text stored in the tag chip 320 and controls the light emitting order of each LED element 410 ′ so that the corresponding text may be displayed on the LED element 410 ′.

In some embodiments, when a specific event (for example, text reception) occurs in the smartphone S according to the setting of a dedicated application, the event content is transmitted to the tag chip 320 in the form of a text to display the LED device 410 '. You can display the corresponding text in.

Although described with reference to the above embodiments, those skilled in the art will understand that various modifications and changes can be made within the scope of the invention without departing from the spirit and scope of the invention as set forth in the claims below. Could be.

1000: Luminescent Accessories for Mobile Phones
100: substrate
200: power unit
300: tag part
400: light emitting unit

Claims (6)

A substrate constituting the body of the accessory;
A power unit disposed on the substrate and configured to receive a search radio wave emitted from an NFC antenna of a smartphone and convert it into electric power;
A tag unit which returns a response signal to the NFC antenna so that the NFC antenna continuously emits the search radio waves; And
A light emitting unit which receives power from the power unit and emits light;
The power unit,
A first antenna for receiving the search wave and converting the search wave into electric power; And
A rectifier converting power received from the first antenna into direct current;
The tag unit,
A second antenna for receiving the search radio wave and returning the response signal; And
Tag tag for applying the response signal to the second antenna,
The tag chip,
A search propagation re-request code for the NFC antenna to emit the search radio continuously;
The search propagation request code is
App execution code for calling a specific application on the smartphone,
The specific application,
While controlling to transmit the search wave emitted from the NFC antenna continuously,
Calculating a power transmission efficiency based on a received signal strength indicator (RSSI) value, which is a strength of a response signal returned from the tag unit,
And determining that the NFC antenna and the light emitting accessory for the mobile phone are in close contact with each other, and controlling the magnitude of the search wave emitted from the NFC antenna so as to transmit only the power necessary for driving the light emitting unit. delete delete delete The method according to claim 1,
The light emitting unit,
A plurality of LED elements; And
Light emitting accessory for a mobile phone, characterized in that it comprises a control element for controlling the light emission order of the plurality of LED elements. The method according to claim 5,
A plurality of the LED elements are arranged in a matrix form, the control element is a light emitting accessory for a mobile phone, characterized in that for controlling the light emitting order of each LED element so that the matrix emits light in a predetermined form.

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