KR20060106619A - Mobile rfid reader, mobile device and method for setting rf tx power - Google Patents

Abstract

Provided are a mobile RFID reader, a portable terminal using the same, and a method of setting RF output power thereof. The RF transmission power setting method includes selecting an RF transmission power of an RF transmission signal used to read tag information contained in an RFID tag, and setting the selected RF transmission power as the transmission power of the RF transmission signal. do. Accordingly, the transmission power of the RF transmission signal used to read the tag information contained in the RFID tag can be set variably, thereby reducing power consumption in the RFID terminal or the portable terminal equipped with the RFID reader.

RFID, RF transmission signal, RF transmission power, ratio (percentage)

Description

Mobile RDF reader, mobile terminal applying the same and RFC transmission power setting method thereof {Mobile RFID Reader, mobile device and method for setting RF TX power}

1 is a view showing a mobile RFID system to which the present invention is applicable;

2 is a block diagram of a mobile terminal equipped with a mobile RFID reader, according to an embodiment of the present invention;

FIG. 3 is a flowchart provided to explain an RF transmission power setting method of the portable terminal shown in FIG. 2;

4 is a diagram illustrating an example of an RF transmission power selection menu screen;

5 is a block diagram of a mobile terminal equipped with a mobile RFID reader according to another embodiment of the present invention;

FIG. 6 is a flowchart for explaining an RF transmission power setting method of the portable terminal shown in FIG. 5;

7 is a diagram illustrating another example of an RF output power selection menu screen.

Explanation of symbols on the main parts of the drawings

100: RFID tag 200, 600: mobile terminal

210, 610: Mobile terminal function block 220, 620: Display

230, 630: mobile terminal control block 240, 640: input unit

300, 700: RFID reader 310: RFID reader control unit

320, 710: Modem 330, 720: RF unit

The present invention relates to a mobile RFID reader, a portable terminal using the same, and a method of setting RF output power thereof, and more particularly, to set a variable output power of an RF transmission signal used to read tag information contained in an RFID tag. The present invention relates to a mobile RFID reader, a portable terminal using the same, and a method of setting RF output power thereof.

RFID (Radio Frequency IDentification) technology has been developed due to the demand for change of production method, change of consumer consciousness, advancement of culture and technology, and elimination of disadvantages of barcode and magnetic card.

RFID is a type of automatic identification data capture (AIDC) technology that reads data stored in a tag containing a microchip in a non-contact manner using radio frequency.

An RFID tag is a device that is attached to various movable items to facilitate tracking and identification of the moving items. In other words, RFID tags are devices that are attached to objects, animals, and people so that they can be automatically identified and tracked through the RFID reader.

The RFID reader may include additional data that is fixed to the identification number of the object associated with the RFID tag, and the RFID tag generally contains information programmed for the object.

Conventional bar code systems require manual scanning, but in RFID systems it is possible to automatically identify objects using the information described above.

As described above, in the RFID system, automatic identification and location tracking are possible, so that the present invention can be applied to various fields, such as libraries, logistics distribution such as large marts, and rental businesses such as records, books, and DVDs. Compared to the system, there is an advantage of more efficient goods management.

Recent issues in RFID systems include ways to reduce power consumption in RFID readers, interference between RFID readers that can occur when multiple RFID readers attempt to read one or more RFID tags in a dense area. This is a method for preventing a problem, a method for improving the operational convenience of a user who uses an RFID reader, and a search for an efficient solution for them is required.

The present invention has been made to solve the above problems, and an object of the present invention is to prevent the user from selecting too many RFID tags, rather than inconvenience, to prevent interference between RFID readers, In order to improve the operational convenience and reduce the power consumption required to read the tag information contained in the RFID tag, the transmission power of the RF transmission signal used to read the tag information contained in the RFID tag is variably set. The present invention provides a mobile RFID reader, a portable terminal using the same, and a method of setting RF output power thereof.

According to the present invention for achieving the above object, the RF transmission power setting method comprises the steps of selecting the RF transmission power of the RF transmission signal used to read the tag information contained in the RFID tag; And setting the selected RF transmission power as the transmission power of the RF transmission signal.

In addition, the RF transmission power is preferably a ratio with respect to the maximum transmission power of the RF transmission signal that can be generated.

The method may further include determining whether the RF transmission power setting method transmits an RF transmission signal at the set RF transmission power and whether reading of tag information contained in the RFID tag is successful.

The RF transmission power setting method may further include: selecting an RF transmission power different from a pre-selected RF transmission power when it is determined that it fails to read the tag information contained in the RFID tag; And setting the selected other RF transmission power as the transmission power of the RF transmission signal.

In addition, the selected other RF transmitting power is preferably larger than the pre-selected RF transmitting power.

The RF transmission power setting method may further include receiving information about an RF transmission power input through any one of a menu screen and a shortcut key, wherein the selecting step is based on the transmitted information. In addition, it is preferable to select the RF transmission power of the RF transmission signal used to read the tag information contained in the RFID tag.

In addition, the information on the RF transmission power input in the transfer step, it is preferable that the information on any one of the ratio of the maximum transmission power of the RF transmission signal, and the reach of the RF transmission signal.

The selecting step may automatically select the RF transmission power using an application written to automatically select the RF transmission power.

The RF transmission power setting method may further include determining a channel state, and the selecting may include selecting the RF transmission power based on the identified channel state.

In the selecting step, the RF transmission power may be selected according to a control signal received from an external device.

On the other hand, RF transmission power setting method according to the present invention, the step of selecting any one of the generateable RF transmission signals; And setting the RF transmission signal used to read tag information contained in the RFID tag to the selected RF transmission signal.

On the other hand, according to the present invention, a portable terminal equipped with an RFID reader that transmits an RF transmission signal and reads tag information contained in an RFID tag, the RF of the RF transmission signal used to read the tag information contained in the RFID tag A portable terminal control block for selecting the output power; And an RFID reader controller provided in the RFID reader and configured to set the selected RF transmission power as transmission power of the RF transmission signal.

In addition, the RF transmission power is preferably a ratio with respect to the maximum transmission power of the RF transmission signal that can be generated.

In addition, the RFID reader controller may determine whether it is successful in reading tag information contained in the RFID tag by transmitting an RF transmission signal at the set RF transmission power.

If it is determined that the portable terminal control block fails to read the tag information contained in the RFID tag by the RFID reader controller, the portable terminal control block selects an RF transmitter power different from the pre-selected RF transmitter power, and the RFID reader controller The selected other RF transmission power may be set as the transmission power of the RF transmission signal.

In addition, the selected other RF transmitting power is preferably larger than the pre-selected RF transmitting power.

The portable terminal control block is used to receive information on the RF transmission power input through any one of a menu screen and a shortcut key, and to read tag information included in the RFID tag based on the transmitted information. It is preferable to select the RF transmission power of the RF transmission signal.

In addition, the input information about the RF transmission power, it is preferable that the information on any one of the ratio of the maximum transmission power of the RF transmission signal, and the reach of the RF transmission signal.

The portable terminal control block may automatically select the RF transmission power using an application written to automatically select the RF transmission power.

The portable terminal control block may select the RF transmission power based on the identified channel state.

The portable terminal control block may select an RF transmission power according to a control signal received from an external device.

On the other hand, according to the present invention, a portable terminal equipped with an RFID reader that transmits an RF transmission signal and reads tag information contained in an RFID tag includes: a portable terminal control block for selecting any one of generateable RF transmission signals; And an RFID reader controller provided in the RFID reader and configured to set an RF transmission signal used for reading tag information included in the RFID tag as the selected RF transmission signal.

On the other hand, according to the present invention, a portable terminal equipped with an RFID reader that transmits an RF transmission signal and reads tag information contained in an RFID tag, the RF of the RF transmission signal used to read the tag information contained in the RFID tag And a portable terminal control block for selecting a transmission power and setting the selected RF transmission power as the transmission power of the RF transmission signal.

On the other hand, according to the present invention, the RFID reader for transmitting the RF transmission signal to read the tag information contained in the RFID tag, the RF transmission signal used to read the tag information contained in the RFID tag, selected by the external control block And an RFID reader controller configured to set the RF transmission power of the RF transmission power to the transmission power of the RF transmission signal.

On the other hand, according to the present invention, the RFID reader for transmitting the RF transmission signal to read the tag information contained in the RFID tag, the RF transmission signal used to read the tag information contained in the RFID tag, selected by the external control block The RF transmission power of is set to the transmission power of the RF transmission signal.

Hereinafter, with reference to the drawings will be described the present invention in more detail.

1 is a diagram illustrating a mobile radio frequency identification (RFID) system to which the present invention is applicable. As shown in FIG. 1, a mobile RFID system includes at least one RFID tag 100 and a portable terminal 200 that recognizes the RFID tag 100.

The mobile terminal 200 is a device that a user can carry, such as a mobile phone or a personal digital assistant (PDA), and can provide text, graphic information, etc. to the user through a display. The mobile terminal 200 is equipped with a mobile RFID reader capable of reading tag information contained in the RFID tag 100.

In the RFID system, the RFID tag 100 may be attached to fixed items, and the portable terminal 200 may be carried by a user and have mobility. As such an RFID system environment, a case in which a user having the mobile terminal 200 shopping a mart in which articles with the RFID tag 100 are displayed is displayed. Importantly, the present invention can be applied to an environment in which the RFID tag 100 is fixed and a mobile RFID reader mounted on the mobile terminal 200 moves.

Meanwhile, although only one portable terminal 200 is illustrated in the RFID system illustrated in FIG. 1, the present invention may be applied to an RFID system including a plurality of portable terminals.

Hereinafter, the portable terminal 200 equipped with the RFID reader illustrated in FIG. 1 will be described in detail with reference to FIG. 2. 2 is a block diagram of a portable terminal equipped with a mobile RFID reader according to an embodiment of the present invention.

As shown in FIG. 2, the mobile terminal 200 includes a mobile terminal function block 210, a display 220, a mobile terminal control block 230, and an input unit 240, and an RFID reader 300. Is equipped.

The mobile terminal function block 210 is a block for performing a function unique to the mobile terminal, such as a telephone call, data communication, or providing an additional function.

The display 220 displays an operation state of the portable terminal, a graphical user interface (GUI) such as a menu screen, and the like, under the control of the portable terminal function block 210, and provides the same to the user.

The portable terminal control block 230 controls the portable terminal function block 210 according to a user's operation command input through the input unit 240 and displays the corresponding information and the corresponding GUI on the display 220.

The RFID reader 300 reads tag information contained in the RFID tag 100 and includes an RFID reader controller 310, a modem 320, and an RF unit 330 as shown in FIG. 2.

The modem 320 generates a signal to be transmitted to the RFID tag 100 through modulation, and the RF unit 330 generates an RF signal generated by processing the modulated signal output from the modem 320 through an RF signal through an antenna. Send to the tag 100.

In addition, the RF unit 330 converts the tag information received from the RFID tag 100 into a baseband signal, and the modem 320 demodulates the tag information output from the RF unit 330. The demodulated tag information is transferred to the mobile terminal control block 230 through the RFID reader controller 310.

The RFID controller 310 controls operations of the modem 320 and the RF unit 330 according to a control command input through the mobile terminal control block 230.

Hereinafter, a process of setting the transmission power of the RF transmission signal used to read the tag information contained in the RFID tag 100 by the portable terminal 200 illustrated in FIG. 2 will be described in detail with reference to FIG. 3. . FIG. 3 is a flowchart provided to explain an RF transmission power setting method of the portable terminal shown in FIG. 2.

Referring to FIG. 3, first, the portable terminal control block 230 is abbreviated as 'output power of an RF transmission signal used to read tag information included in the RFID tag 100' (hereinafter, 'RF transmission power'). .) Is selected (S410).

Specifically, in step S410, the portable terminal control block 230, 'the ratio (percentage) to the maximum output power of the RF output signal can be generated (hereinafter, abbreviated as' RF transmission power ratio (percentage)'). You can choose.

For example, the mobile terminal control block 230 may determine the RF transmission power ratio by 1) 100% of the maximum transmission power, 2) 80% of the maximum transmission power, 3) 60% of the maximum transmission power, or 4) the maximum transmission power. 40% and so on.

At this time, the mobile terminal control block 230 is based on the user's input through the 'RF transmission power selection menu screen' 1) select the RF transmission power ratio, or 2) the application written to automatically select the RF transmission power ratio RF transmission power ratio can be selected.

4 illustrates a part of the mobile terminal 200 in which the 'RF transmission power selection menu screen' is displayed on the display 220.

As shown in FIG. 4, the RF transmission power selection menu screen displays “100%”, “80%”, “60%”, “40%”, and “Auto” menu items. Any one of the displayed menu items may be selected using the keys provided at 240.

If the user selects " 80% ", the mobile terminal control block 230 selects the RF transmission power ratio as 80% of the maximum transmission power. On the other hand, when the user selects "automatic", the portable terminal control block 230 automatically sets the RF transmission power ratio by using an application written to automatically select the RF transmission power ratio.

At this time, the automatically set ratio is 1) the median value of the maximum transmission power (50%), 2) the RF transmission power ratio most recently selected, 3) the RF transmission power ratio with the highest frequency of selection, and 4) the selection so far. It may be any one of the average value of the RF transmission power ratios.

On the other hand, if the user selects "auto", the mobile terminal control block 230 to determine the channel state through the mobile terminal function block 310, and implements to select the RF transmission power ratio based on the identified channel state It is also possible.

Meanwhile, the RF transmission power ratio input by the user may be input using a shortcut key provided in the input unit 240 without using a menu screen.

Hereinafter, the steps after step S410 will be described in detail with reference to FIG. 3 again.

After step S410, the RFID reader control unit 310 'RF transmission signal used to read the tag information contained in the RFID tag 100, the RF transmission power selected by the mobile terminal control block 230 in step S410 (hereinafter, 'RF transmission signal' is set to the transmission power (S420).

In detail, the RFID reader controller 310 may determine the RF transmission power selected by the portable terminal control block 230 in step S410, 1) a register provided in the RFID reader control unit 310, 2) a register provided in the modem 320, and 3 By storing in any one of the registers provided in the RF unit 330, it is set to the transmission power of the RF transmission signal.

Thereafter, the mobile terminal control block 230 determines whether the user inputs a 'command to read the RFID tag 100' (hereinafter, abbreviated as 'reading command') from the user (S430).

The reading command input can be input by the user using a shortcut key provided on the menu screen or the input unit 240, similar to the above-described RF transmission power input.

If it is determined in step S430 that a reading command is input (S430-Y), the portable terminal control block 230 transmits the input reading command to the RFID reader controller 310 (S440).

The RFID reader controller 310 receiving the reading command in step S440 controls the modem 320 to generate a signal to be transmitted to the RFID tag 100 through modulation (S450).

In addition, the RFID reader controller 310 controls the RF unit 330 to generate an RF transmission signal by RF signal processing the modulation signal output from the modem 320 (S460).

The RF unit 330 transmits the RF transmission signal to the RFID tag 100 at the transmission power set by the RFID reader controller 310 in operation S420 (S470).

Thereafter, the RFID reader controller 310 determines whether the RFID information is received from the RFID tag 100 through the RF unit 330 and the modem 320 (S480).

In operation S480, the RFID reader controller 310 may determine whether the RFID reader controller 310 is successful in reading the tag information contained in the RFID tag 100 as the RF transmission signal transmitted according to the set transmission power.

If it is determined in step S480 that the tag information has not been received (that is, failed to read the tag information) (S480-N), the RFID reader controller 310 transmits a tag information not received message to the mobile terminal control block 230. Transfer to (S490).

The mobile terminal control block 230 receiving the tag information non-receipt message in step S490 selects an RF transmission power larger than the RF transmission power selected in step S410 (S500).

Then, the RFID reader controller 310 sets the RF transmission power selected by the portable terminal control block 230 as the transmission power of the RF transmission signal in step S500 (S510).

Accordingly, the RF unit 330 transmits the RF transmission signal to the RFID tag 100 using the transmission power set by the RFID reader control unit 310 in step S510 (S520), and is subsequently performed again from step S480. .

On the other hand, if it is determined in step S480 that the tag information has been received (that is, successful in reading the tag information) (S480-Y), the RFID reader control unit 310 receives the received tag information in the mobile terminal control block 230 To be transmitted (S530).

Then, the portable terminal control block 230 transmits the tag information to an external server (not shown) through the portable terminal function block 210, and to the article with the RFID tag 100 containing the tag information from the external server. Obtain information about (S540).

The mobile terminal control block 230 displays the article information obtained in operation S540 on the display 220 so that the user can refer to the information on the display 220 (S550).

On the other hand, in setting the RF transmission power selected by the portable terminal control block 230 as the transmission power of the RF transmission signal in the present embodiment, 1) the RFID reader controller 310 sets the RF transmission power selected by the portable terminal control block 230. 2), 2) a register provided in the modem 320, and 3) a register provided in the RF unit 330, thereby setting the output power of the RF transmission signal.

However, the RF transmission power selected by the portable terminal control block 230 may be stored in any one of 1) a register provided in the portable terminal control block 230 or 2) a memory (not shown) provided in the portable terminal 600. Of course you can.

In this case, in step S440, the portable terminal control block 230 is preferably implemented to transmit the information on the RF transmission power stored with the input reading command to the RFID reader controller 310.

Hereinafter, another embodiment of the present invention will be described in detail with reference to FIGS. 5 and 6. 5 is a block diagram of a mobile terminal equipped with a mobile RFID reader according to another embodiment of the present invention.

The RFID reader 700 of the portable terminal 600 illustrated in FIG. 5 is different from the portable terminal 200 illustrated in FIG. 2 in that the RFID controller 310 is not provided. The portable terminal control block 630 provided in the portable terminal 600 illustrated in FIG. 5 also serves as an omitted RFID controller. That is, the portable terminal control block 630 controls the operations of the modem 710 and the RF unit 720 provided in the RFID reader 700.

In addition, the portable terminal function block 610, the display 620, the portable terminal control block 630, and the modem 710 provided in the input unit 640 and the RFID reader 700 illustrated in FIG. 5, and the RF unit ( Detailed description of the 720 is, the portable terminal function block 210, the display 220, the portable terminal control block 230, and the input unit 240 and the modem 320 provided in the RFID reader 300 shown in FIG. And, since it can be inferred from the detailed description of the RF unit 330 will be omitted.

Hereinafter, a process of setting the transmission power of the RF transmission signal used to read the tag information contained in the RFID tag 100 by the portable terminal 600 illustrated in FIG. 5 will be described in detail with reference to FIG. 6. . FIG. 6 is a flowchart provided to explain an RF transmission power setting method of the portable terminal shown in FIG. 5.

First, the portable terminal control block 630 selects an RF transmission power (S810). At this time, the portable terminal control block 630 can be implemented to select the RF transmission power ratio is the same as the above-described embodiment.

Thereafter, the portable terminal control block 630 sets the RF transmission power selected in step S810 as the transmission power of the RF transmission signal (S820).

Specifically, the mobile terminal control block 630 stores the RF transmission power selected in step S810 in any one of 1) a register provided in the modem 710, 2) a register provided in the RF unit 720, RF transmission signal The output power of is set.

Thereafter, the portable terminal control block 630 determines whether a reading command is input from the user (S830).

If it is determined in step S830 that a reading command is input (S830 -Y), the portable terminal control block 630 controls the modem 710 to generate a signal to be transmitted to the RFID tag 100 through modulation (S840).

In addition, the portable terminal control block 630 controls the RF unit 720 to generate an RF transmission signal by RF signal processing the modulated signal output from the modem 710 (S850).

The RF unit 730 transmits the RF transmission signal to the RFID tag 100 at the transmission power set by the portable terminal control block 630 in step S820 (S860).

Thereafter, the mobile terminal control block 630 determines whether the tag information is received from the RFID tag 100 through the RF unit 720 and the modem 710 (S870).

If it is determined in step S870 that the tag information is not received (that is, failed to read the tag information) (S870-N), the mobile terminal control block 630 transmits an RF larger than the RF transmission power selected in step S810 The power is selected, and the selected RF transmission power is set as the transmission power of the RF transmission signal (S880).

Accordingly, the RF unit 730 transmits the RF transmission signal to the RFID tag 100 using the transmission power set by the portable terminal control block 630 in step S880 (S890), and then restarts from step S870. Is performed.

If it is determined in step S870 that the tag information has been received (that is, succeeded in reading the tag information) (S870-Y), the mobile terminal control block 630 is an external server (through the mobile terminal function block 210) ( The tag information is transferred to the tag information, and information about the article to which the RFID tag 100 including the tag information is attached is obtained from the external server (S900).

The mobile terminal control block 630 displays the article information obtained in operation S900 on the display 620 so that the user can refer to the information on the display 620 (S910).

In the present embodiment, when the RF transmission power selected by the portable terminal control block 630 is set as the transmission power of the RF transmission signal, the RF transmission power selected by the portable terminal control block 630 is 1) a register provided in the modem 710. 2) By storing in one of the registers provided in the RF unit 720, it is implemented by setting the transmission power of the RF transmission signal.

However, the RF transmission power selected by the mobile terminal control block 630 may be stored in any one of 1) a register provided in the mobile terminal control block 630 or 2) a memory (not shown) provided in the mobile terminal 600. Of course you can. In this case, when the RFID reader 700 needs to operate, the portable terminal control block 630 may be implemented by transferring information on the stored RF transmission power to the modem 710.

Meanwhile, in the above-described embodiments, the RF transmission power ratio is referred to as the 'RF transmission power ratio' (ratio of the maximum transmission power of the RF transmission signal that can be generated), and accordingly, the user uses the RF transmission power selection menu screen. It was assumed that the output power ratio could be entered.

The reason why the ratio of the RF transmission power as the RF transmission power is assumed in consideration of the user's input convenience. This is because it is easier for a user to recognize the RF transmission power ratio than the RF transmission power size in which the RF transmission power is expressed in specific numerical values. That is, the RF transmission power ratio is much easier for the user to feel than the size of the RF transmission power.

In addition, considering that the range of the RF output power size that can be output from the RFID reader is different for each manufacturer, an error may occur when the user inputs the RF output power size out of the range when inputting the RF output power size. On the other hand, when the user inputs the RF transmission power ratio, there is no room for such an error.

In addition, from the standpoint of the portable terminal control blocks 230 and 630 controlling the RFID readers 300 and 700, it is more reasonable to select the RF transmission power ratio rather than the RF transmission power size. As described above, the range of the RF transmission power size that can be output from the RFID readers 300 and 700 varies from manufacturer to manufacturer, because the portable terminal control blocks 230 and 630 need to store all of them for each manufacturer. .

On the other hand, it is of course possible to implement so that the user can input the RF transmission power using other parameters in addition to the RF transmission power ratio.

As another available parameter, the reach of the RF transmission signal can be assumed. In this case, when the user inputs the reach distance of the RF transmission signal through the RF transmission power selection menu screen or the input units 240 and 640, the mobile terminal control blocks 230 and 630 calculate a corresponding RF transmission power ratio. Then, the calculated RF transmission power ratio is selected.

FIG. 7 illustrates a part of the portable terminals 200 and 600 in which a menu screen for selecting the reach distance of the RF transmission signal is displayed on the displays 220 and 620.

As shown in FIG. 7, the menu screen displays "within 30cm", "30cm-1m", "1m-2m", "2m or more", and "auto" menu items, and the user inputs 240, One of the displayed menu items may be selected using the keys provided in 640.

If the user selects "30cm-1m", the mobile terminal control blocks 230 and 630 calculate an RF transmission power ratio suitable for reading the RFID tag 100 located at 30cm-1m, and the calculated RF transmission power ratio Will be selected.

In an environment in which the RFID tag 100 is fixed and the RFID reader mounted on the portable terminal 200 moves, varying the RF transmission power has an important meaning in that the number of RFID tags to be read can be limited.

Since the RFID tags are densely packed, the portable terminal 200 or 600 reads many RFID tags, and the RF transmission power is applied to prevent the display of a lot of item information on the displays 220 and 620 having a relatively small screen size. Because it can reduce. This situation does not occur in an environment in which the RFID reader is fixed and the RFID tag is carried by the user and moved.

When the RF transmission power is reduced, the portable terminal 200 or 600 reads a small number of RFID tags, and a small number of article information is displayed on the displays 220 and 620.

Meanwhile, in the above-described embodiments, the portable terminal control blocks 230 and 630 are described as selecting RF transmission power in accordance with a user's input through a menu screen or a shortcut key, or automatically selecting RF transmission power using an application. It was.

That is, the mobile terminal 200, 600, but only the case of selecting the RF transmission power by itself has been described as an example, it is also possible to implement the present invention in a different method. That is, it may be assumed that the portable terminals 200 and 600 select the RF transmission power according to the control signal received from the external device.

For example, "RF transmit power from external devices located in areas where there is frequent interference between RFID readers and the RF transmit power ratio needs to be limited below a certain rate (for example, a place where many people gather, such as a museum). When receiving the control signal containing the message "limit the ratio to 20% or less", the mobile terminal (200, 600) is to select the RF transmission power to 20%.

Meanwhile, in the above-described embodiments, when failing to read the tag information, the portable terminal control blocks 230 and 630 are implemented to automatically select a larger RF transmission power. However, unlike this, a message indicating that the mobile terminal control blocks 230 and 630 failed to read the tag information is displayed on the display 220 and 620 to inform the user and to display the 'RF transmission power selection menu screen'. By providing the display 220, 620, it is of course possible to implement to input other RF transmission power desired by the user.

In addition, in the above-described embodiments, although the RF transmission power input and the reading command input of the user are implemented separately, the reading command input may be included in the RF transmission power input.

Meanwhile, in the above-described embodiments, the portable terminal function blocks 210 and 610 and the RFID readers 300 and 700 are implemented with separate antennas, but it is of course possible to integrate the antennas into one antenna. .

In addition, in the case of implementing only the RFID readers 300 and 700 in addition to the portable terminals 200 and 600, the technical idea of the present invention may be applied as it is.

In addition, the above-described embodiments may be interpreted as selecting any one of the generateable RF transmission signals and setting the RF transmission signal to the selected RF transmission signal.

As described above, according to the present invention, it is possible to variably set the transmission power of the RF transmission signal used to read the tag information contained in the RFID tag, it is inconvenient for the user to select by reading too many RFID tags It is possible to prevent the occurrence of this in advance.

In addition, it is possible to reduce the transmission power of the RF transmission signal in a region where the RFID readers are concentrated, thereby preventing interference between a plurality of adjacent RFID readers.

And, it helps to reduce the power consumption in the RFID terminal or a portable terminal equipped with an RFID reader.

In addition, as the transmission power of the RF transmission signal, it can be input as a ratio (percentage) to the maximum transmission power that the user can easily feel, enabling convenience for the user's input and preventing occurrence of errors due to misoperation. You can do it.

In addition, in selecting / setting the transmission power of the RF transmission signal, the ratio (percentage) to the maximum transmission power is used, so that the design and operation of the control block can be made very reasonably.

In addition, although the preferred embodiment of the present invention has been shown and described above, the present invention is not limited to the specific embodiments described above, but the technical field to which the invention belongs without departing from the spirit of the invention claimed in the claims. Of course, various modifications can be made by those skilled in the art, and these modifications should not be individually understood from the technical spirit or the prospect of the present invention.

Claims (25)

Selecting an RF transmission power of an RF transmission signal used to read tag information contained in the RFID tag; And And setting the selected RF transmission power as the transmission power of the RF transmission signal. The method of claim 1, The RF transmission power, RF transmission power setting method, characterized in that the ratio to the maximum transmission power of the generated RF transmission signal. The method of claim 1, And transmitting the RF transmission signal with the set RF transmission power, and determining whether the tag information contained in the RFID tag has been successfully read. The method of claim 3, wherein If it is determined that the tag information contained in the RFID tag has failed to be read, selecting an RF transmission power different from the preselected RF transmission power; And And setting the selected other RF transmission power as the transmission power of the RF transmission signal. The method of claim 4, wherein And the selected other RF transmission power is larger than the preselected RF transmission power. The method of claim 1, Receiving the information about the RF transmission power input through any one of the menu screen, and a shortcut key; The selection step, RF transmission power setting method, characterized in that for selecting the RF transmission power of the RF transmission signal used to read the tag information contained in the RFID tag based on the transmitted information. The method of claim 6, Information on the RF transmission power input in the transfer step, RF transmission power setting method characterized in that the information on any one of the ratio of the maximum transmission power of the RF transmission signal, and the reach of the RF transmission signal. The method of claim 1, The selection step, RF transmission power setting method characterized in that the automatic selection of the RF transmission power using an application written to automatically select the RF transmission power. The method of claim 1, Determining a channel status; The selection step, RF transmission power setting method, characterized in that for selecting the RF transmission power based on the identified channel state. The method of claim 1, The selection step, RF transmission power setting method, characterized in that for selecting the RF transmission power in accordance with a control signal received from an external device. Selecting one of the generateable RF transmission signals; And And setting the RF transmission signal used to read tag information contained in the RFID tag to the selected RF transmission signal. A portable terminal equipped with an RFID reader for transmitting an RF transmission signal and reading tag information contained in an RFID tag, A portable terminal control block for selecting an RF transmission power of an RF transmission signal used to read tag information contained in the RFID tag; And And an RFID reader controller provided in the RFID reader and configured to set the selected RF transmission power as transmission power of the RF transmission signal. The method of claim 12, The RF transmission power, And a ratio of the maximum transmitting power of the generated RF transmitting signal. The method of claim 12, The RFID reader control unit, And transmitting an RF transmission signal at the set RF transmission power, and determining whether or not it succeeds in reading tag information contained in the RFID tag. The method of claim 14, The mobile terminal control block, If it is determined that the RFID reader controller fails to read the tag information contained in the RFID tag, the RF reader power different from the preselected RF power is selected. The RFID reader control unit, And setting the selected other RF transmission power as the transmission power of the RF transmission signal. The method of claim 15, And the selected other RF transmitting power is larger than the preselected RF transmitting power. The method of claim 12, The mobile terminal control block, The RF transmission power of the RF transmission signal used to receive the information on the RF transmission power input through any one of a menu screen and a shortcut key, and to read the tag information contained in the RFID tag based on the transmitted information. A mobile terminal, characterized in that the selection. The method of claim 17, The information on the input RF transmission power, And information about any one of a ratio of a maximum transmission power of the RF transmission signal and a reach distance of the RF transmission signal. The method of claim 12, The mobile terminal control block, A mobile terminal, characterized in that for automatically selecting the RF transmission power using an application written to automatically select the RF transmission power. The method of claim 12, The mobile terminal control block, And the RF transmitting power is selected based on the identified channel state. The method of claim 12, The mobile terminal control block, The portable terminal, characterized in that for selecting the RF transmission power in accordance with a control signal received from an external device. A portable terminal equipped with an RFID reader for transmitting an RF transmission signal and reading tag information contained in an RFID tag, A portable terminal control block for selecting any one of the generateable RF transmission signals; And And an RFID reader controller provided in the RFID reader and configured to set an RF transmission signal used to read tag information contained in the RFID tag as the selected RF transmission signal. A portable terminal equipped with an RFID reader for transmitting an RF transmission signal and reading tag information contained in an RFID tag, And a portable terminal control block for selecting an RF transmission power of an RF transmission signal used to read tag information contained in the RFID tag, and setting the selected RF transmission power as the transmission power of the RF transmission signal. Portable terminal. An RFID reader for transmitting an RF transmission signal to read tag information contained in an RFID tag, And an RFID reader controller configured to set an RF transmission power of an RF transmission signal used to read tag information contained in the RFID tag, selected by an external control block, to the transmission power of the RF transmission signal. RFID reader. An RFID reader for transmitting an RF transmission signal to read tag information contained in an RFID tag, And an RF transmission power of an RF transmission signal used for reading tag information contained in the RFID tag selected by an external control block, to be set as the transmission power of the RF transmission signal.

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