KR20100043383A - System for semi passive rfid tag and driving method thoereof - Google Patents

Abstract

PURPOSE: A system for a semi passive RFID tag and a driving method thereof are provided to prevent the power consumption for tag operation by activating a tag which receives an optical signal from an RFID reader. CONSTITUTION: An optical signal transmitter generates and transmits an optical signal, and an RFID signal reader discriminates the RFID signal originated from a tag unit. The tag unit includes an optical signal collecting unit(121) which receives the optical signal, an optical signal recognition unit(123) which recognizes the received optical signal, an RFI signal generating unit(125) which generates and transmits the RFID signal, and a control unit(127). When recognizing the optical signal, the control unit wakes up the RFID signal generating unit.

Description

System for semi passive RFID tag and driving method thoereof}

The present invention relates to a compliant RFID tag system and an operation method, and more particularly, to a compliant RFID tag system and an operation method which can reduce battery consumption in a tag.

The Radio Frequency Identification (RFID) system consists of an RFID reader (including an antenna that is connected to the reader to send radio waves to a tag), a tag that stores information and exchanges data with the RFID reader, and other RFID readers and enterprise applications ( E.g., middleware, applications relayed between Enterprise Resource Planning (ERP), Object Naming Service (ONS) that tells the Internet Protocol (IP) address where the information can be retrieved with EPC (Electronic Product Code) code, and EPC It consists of EPC Information Service (EPCIS), which has been processed to make data useful for the enterprise.

A tag is an IC chip with an integrated antenna and is inserted into equipment or objects and recognized through a reader using radio frequency. The tag has power depending on the presence or absence of power, and can be operated without sensing the radio wave of the reader.It has power to the passive tag that is operated by generating power by the electromagnetic field of the reader without supplying power directly from inside or outside. It is divided into conformity type which is operated by the sensor which detected the electric wave. In general, the passive type has the advantage of being read only, light, inexpensive, and semi-permanent, but has a short recognition distance and consumes more power in the reader. Active type shows the form of read / write, reduces the power required by the reader, and has the advantage of being able to distance the recognition distance, but there is a limit on the operation time because the power is always used. The price is expensive. In the case of Jundong Dynamic, the advantages of both are combined, so that the recognition distance can be set up with a power supply, and when the radio wave of the reader is detected, the unnecessary power consumption is reduced.

An object of the present invention is to provide a compliant RFID tag system and an RFID tag operating method capable of efficiently managing a battery in a tag.

The technical problems to be achieved by the present invention are not limited to the technical problems mentioned above, and other technical problems not mentioned above are clearly understood by those skilled in the art from the following description. Could be.

In order to achieve the above object, the present invention provides an RFID reader unit for generating and transmitting an optical signal and identifying a radio frequency identification (RFID) signal; And a tag unit which wakes up when the optical signal is received and recognized, and transmits an RFID signal that is identifiable by the RFID reader unit.

The RFID reader may include an optical signal transmitter configured to generate and transmit the optical signal; An RFID signal reading unit for identifying an RFID signal transmitted from the tag unit, wherein the tag unit comprises: an optical signal condenser receiving an optical signal transmitted from the RFID reader unit; An optical signal recognition unit recognizing the received optical signal; An RFID signal generation unit for generating and transmitting an RFID signal identifiable by the RFID signal reading unit; And when the optical signal is recognized by the optical signal recognition unit, it is preferable to include a control unit for controlling to wake up the RFID signal generation unit to generate and transmit the RFID signal. In this case, the RFID signal generator and the controller may be integrally formed, and the optical signal concentrator may be configured as a condenser or a convex lens. In addition, the optical signal is preferably a laser.

Meanwhile, the present invention provides an RFID tag operating method for transmitting an RFID signal from a tag and identifying the RFID signal in an RFID reader, wherein the tag is driven by an optical signal transmitted from the RFID reader to transmit an RFID signal. The present invention provides a method for operating a compliant RFID tag.

Here, the optical signal is preferably a laser.

As described above, according to the present invention, the compliant RFID tag system and the operating method of the present invention operate only a specific tag that receives the optical signal by using an optical signal transmitted from an RFID reader unit, thereby operating other tags. The power consumption can be prevented, thereby improving the efficiency of the battery as a whole.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a view showing a compliant RFID tag system according to an embodiment of the present invention.

Referring to FIG. 1, the compliant RFID tag system according to the present embodiment generates and transmits an optical signal, receives an RFID reader 110 capable of identifying an RFID signal, and receives and recognizes the optical signal. In one case, the tag unit 120 includes a tag unit 120 that wakes up and transmits an RFID signal identifiable by the RFID reader unit.

The RFID reader unit 110 generates and transmits an optical signal and is capable of identifying a radio frequency identification (RFID) signal. The RFID signal means a communication signal between the RFID reader unit and a tag, but the present invention In this case, the signal transmitted from the tag unit is limited. Accordingly, the part of receiving the RFID signal and identifying the same part is the same as the existing RFDI reader, but has a feature of generating and transmitting an optical signal.

As mentioned earlier, the conventional semi passive RFID tag system is the same in that it has a power source like an active type, but it is different from the active type in that it operates when a radio wave of a reader is detected. Here, detecting the radio wave of the reader means that a sensor capable of detecting the radio wave is provided. As shown in FIG. 2, in the characteristic of the radio wave, the sensor of all tags within a predetermined radius of the reader may be used. Radio waves are detected. When the RFID tag detects the radio wave of the reader, the RFID tag wakes up so that the RFID chip can be driven by supplying power to the RFID chip in the idle state. Only the RFID chip in the tag of which the reader is interested among the chips normally performs communication using the reader and the RFID signal, and the RFID chip in the other tag is a wake-up but is separate from the reader's interest and thus performs separate communication. You will not. However, when the RFID chip wakes up in this manner, unnecessary power consumption occurs during wakeup or while it is waked up. This power consumption results in a problem of reducing the power duration of each tag. Therefore, the present embodiment proposes an RFID reader portion that uses an optical signal without using radio waves as a signal to wake up the RFID chip in each tag.

When the tag unit 120 receives and recognizes an optical signal transmitted from the RFID reader unit, the tag unit 120 wakes up to transmit an RFID signal that is identifiable by the RFID reader unit. That is, the tag unit wakes up the embedded RFID chip when the optical signal transmitted from the RFID reader unit is recognized or sensed. The tag unit drives the wakeup RFID chip to communicate with the RFID reader unit. do.

Receiving and recognizing the optical signal in the tag unit may be expected to be a tag unit of interest in the RFID reader unit. Since the optical signal may be adjusted to have a directionality or the range may be easily set in some cases, the optical signal transmission may be adjusted according to the direction or range of the tag portion of interest in the RFID reader unit as shown in FIG. 3. Therefore, at least one tag portion in the direction of the optical signal transmitted from the RFID reader portion or a tag portion within the range of the optical signal will be of interest to the RFID reader portion, and other tags will be out of interest. Accordingly, by appropriately adjusting the transmitted optical signal, the RFID reader unit can wake up only the tag unit of interest and perform RFID communication. This can reduce unnecessary power consumption by not waking up tags that are not of interest.

In summary, the compliant RFID tag system according to the present embodiment uses an optical signal as a wake-up signal so that only the tag portion within a desired direction or range wakes up, thereby preventing unwanted wakeup of the tag portion. Reduce unnecessary power consumption due to wake up.

To this end, the RFID reader 110 includes an optical signal transmitter 111 for generating and transmitting the optical signal, and an RFID signal reading unit for identifying the RFID signal transmitted from the tag unit as shown in FIG. 4. 113), and other elements are the same as in the prior art, so a description thereof is omitted.

The optical signal transmitter 111 is an element that generates and transmits an optical signal as a wake-up signal. Specifically, the optical signal transmitter 111 may be configured as a light bulb, a laser generator, or the like. The light bulb is useful when the RFID reader is interested in a tag within a predetermined range, and the laser generator is useful when a laser is interested in a tag located in a certain direction due to the characteristics of the laser. Of course, in the former case, it would be desirable to be able to adjust the range of the optical signal, and in the latter case, it would be desirable to be able to adjust the direction.

The RFID signal reading unit 113 is an element for performing RFID communication with the RFID chip waked up within a tag located in the range or direction of the optical signal. In FIG. 4, only the RFID signal is received from the RFID chip. Indicated. Of course, it is also possible to transmit the RFID signal to the RFID chip as needed, but this is beyond the point.

Specifically, as shown in FIG. 5, the tag unit 120 includes an optical signal condenser 121 for receiving an optical signal transmitted from the RFID reader and an optical signal recognition unit 123 for recognizing the received optical signal. ), When the RFID signal generating unit 125 generates and transmits an RFID signal identifiable by the RFID signal reading unit and the optical signal is recognized by the optical signal recognizing unit, wakes up the RFID signal generating unit and generates an RFID signal. And it is preferable that the control unit 127 to control to send.

The optical signal condenser 121 is an element for more effectively receiving the optical signal. In summary, the optical signal condenser 121 condenses the optical signal. Unlike the radio wave, the optical signal should be directed toward the optical signal transmitter of FIG. 4 corresponding to the light source. Moreover, when the optical signal is directional like a laser, it needs to be positioned exactly in that direction, which may add inconvenience to use. Therefore, it is preferable that the optical signal concentrator comprises an element such as a condenser or a convex lens so that the optical signal is easily received.

The optical signal received through the optical signal concentrator is recognized by the optical signal recognition unit 123, and specifically, an optical sensor, a laser sensor, or the like may be applied. For example, the photodiode and the phototransistor can be easily configured using the photodiode and the phototransistor, where the photodiode and the phototransistor should be configured as light-receiving elements instead of light-emitting elements.

The RFID signal generation unit 125 communicates with the RFID control unit using an RFID signal as an element corresponding to the RFID chip in the tag unit described above, and in this embodiment, generates and transmits an RFID signal for convenience of description. It is shown. Before the RFDI signal generator generates and transmits an RFID signal, the RFDI signal generator must first wake up in an idle state, which is performed by the controller 127. In addition, the control unit also controls the generation and transmission of the RFID signal of the RFID signal generator, in some cases may be formed integrally with the RFID signal generator.

Let's look at the operation of the compliance-type RFID tag system described above with reference to FIG. Fig. 6 shows the operation of the tag unit. The RFID reader unit is identical in operation to a conventional RFID reader except that the RFID reader transmits an optical signal toward a tag of interest or covers a certain range.

Referring to FIG. 6, when an optical signal is detected (S 310), the tag unit wakes up the RFID signal generator (S 320), which immediately maintains the RFID signal generator in an idle state when the optical signal is not detected. It means that it is the same as in the prior art. The RFID signal generator, which has been woken up by the optical signal, generates and transmits an RFID signal (S330) to communicate with the RFID reader.

In summary, in an RFID tag operating method of transmitting an RFID signal from a tag and identifying the RFID signal in an RFID reader, the tag is driven by an optical signal transmitted from the RFID reader to transmit an RFID signal. I can arrange it with a thing.

It will be described in detail, first detecting the optical signal transmitted from the RFID reader unit; When the optical signal is detected, switching the idle control unit to a wake-up state, supplying power to the RFID signal generation unit in which the power is off, and supplying power. Performing the communication between the RFID signal generation unit and the RFID reader unit, after the completion of the communication, switching the wake-up state to the idle state, and turning off the power of the RFID signal generation unit. If the optical signal is not detected, the idle state is continuously maintained so that the power of the RFID signal generator is turned off, and only when the optical signal is recognized, the RFID signal generator is turned on as a wake-up state to communicate with the RFID reader. By eliminating unnecessary power supplied to the RFID signal generation unit, power consumption can be reduced.

In general, since the tag portion of interest in the RFID reader portion is likely to be one at a time point, it is preferable that the optical signal has a directionality like a laser. Of course, a plurality of tag parts included in a certain range may be of interest, and in this case, an optical signal transmitting unit that may cover a certain range, such as a light bulb, may be used. In the case of using a directional optical signal such as a laser, as mentioned above, a condenser or the like can be used as the optical signal condenser of the tag part, but even then, the RFID reader part transmitting the laser has to pay special attention to the direction control. . Therefore, when using a directional optical signal as a wake-up signal, it is desirable to minimize waste of unnecessary resources by setting a path that the tag portion must pass. For example, by arranging the RFID reader unit in an entrance, a narrow passage, etc., it is possible to minimize the waste of resources for irradiating a directional optical signal such as a laser to the tag or a waste of resources for fitting the tag to the irradiated optical signal. Can be.

Although the technical spirit of the present invention has been described in detail according to the above-described preferred embodiment, it should be noted that the above-described embodiment is for the purpose of description and not of limitation. In addition, those skilled in the art will understand that various embodiments are possible within the scope of the technical idea of the present invention.

1 is a block diagram showing a compliant RFID tag system according to an embodiment of the present invention.

Figure 2 is a schematic diagram showing the operating environment of a conventional compliant RFID tag system.

Figure 3 is a schematic diagram showing the operating environment of the compliant RFID tag system of Figure 1;

4 is a block diagram showing in detail the configuration of the RFID reader unit constituting the compliant RFID tag system of FIG.

FIG. 5 is a block diagram illustrating in detail the configuration of a tag unit constituting the compliant RFID tag system of FIG. 1. FIG.

6 is a flowchart illustrating an operation of a tag unit during operation of the compliant RFID tag system of FIG. 1.

* Description of the symbols for the main parts of the drawings *

110 ... RFID Reader 120 ... Tag

111 ... optical signal transmitter 121 ... optical signal concentrator

123 Optical signal recognition unit 127 Control unit

Claims (10)

An RFID reader unit for generating and transmitting an optical signal and identifying a radio frequency identification (RFID) signal; And When receiving and recognizing the optical signal, the tag unit wakes up and transmits an RFID signal identifiable by the RFID reader unit. Compliant dynamic RFID tag system comprising a. The method of claim 1, The RFID reader unit An optical signal transmitter for generating and transmitting the optical signal; An RFID signal reading unit for identifying the RFID signal transmitted from the tag unit; Compliant dynamic RFID tag system comprising a. The method of claim 1, The tag unit An optical signal condenser for receiving an optical signal transmitted from the RFID reader unit; An optical signal recognition unit recognizing the received optical signal; An RFID signal generator for generating and transmitting an RFID signal identifiable by the RFID signal reading unit; And When the optical signal is recognized by the optical signal recognition unit, the control unit for waking up the RFID signal generation unit and controls to generate and send the RFID signal Compliance type RFID tag system, characterized in that comprises a. The method of claim 3, wherein The RFID signal generation unit and the control unit according to claim, characterized in that the integrally formed RFID tag system. The method of claim 3, wherein The optical signal concentrator is a compliant RFID tag system, characterized in that the condenser or convex lens. The method of claim 3, wherein The optical signal recognition unit is a compliant RFID tag system, characterized in that it comprises a photo-diode or photo-transistor. 7. The method according to any one of claims 1 to 6, And the optical signal has a directionality. The method of claim 7, wherein Compliance type RFID tag system, characterized in that the optical signal is a laser. An RFID tag operating method of transmitting an RFID signal from a tag and identifying the RFID signal by an RFID reader, The tag is driven by the optical signal transmitted from the RFID reader unit to transmit an RFID signal, characterized in that for transmitting an RFID signal. The method of claim 9, When the optical signal is not recognized, the tag is in an idle state, and the RFID signal generator is turned off. When the optical signal is recognized, the tag is in a wake-up state and the RFID signal generator is turned on. A method for operating a compliant RFID tag characterized in that the communication with the RFID reader unit. Sensing the optical signal transmitted from the RFID reader unit; When the optical signal is detected, switching a control unit in an idle state to a wake-up state and supplying power to an RFID signal generation unit in which power is off; Performing communication with the RFID signal generator, which is powered, and the RFID reader; After completing the communication, switching the wake-up control unit to the idle state and turning off the power of the RFID signal generation unit. Compliance type RFID tag operation method comprising a.

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