KR200398970Y1 - RF card having tag of heterogeneity with different frequency band - Google Patents

Abstract

The present invention is equipped with each radio frequency tag having a different frequency band using a single card, so that the traffic charges having different frequency bands, various automation projects, distribution business, livestock management, access control, time and attendance management, logistics management, parking The present invention relates to an RF card equipped with a heterogeneous tag having a different frequency band which can be selectively used interchangeably among various fields such as management, for the card 100 and a low frequency band mounted on one side of the card 100. The tag 200 and the high frequency band tag 300 mounted on the other side of the card 100 is characterized in that it is made.

Description

RF card having tag of heterogeneity with different frequency band}

The present invention relates to a card to which RFID technology is applied, and more particularly, by mounting each radio frequency tag having a different frequency band using a single card, traffic billing having a different frequency band, various automation business, distribution business The present invention relates to an RF card loaded with heterogeneous tags having different frequency bands that can be selectively used among various fields such as livestock management, access control, time and attendance management, logistics management, and parking management.

In general, RFID (Radio Frequency Identification) is a wireless identification system that wirelessly transmits and transmits specific information using a radio frequency using a small semiconductor chip. In the case of a conventional magnetic recognition or barcode recognition system, a specific indication that can be identified externally is required. In addition, it has been spotlighted as an alternative means for solving the problem that the recognition rate decreases with time due to weakening or damaging magnetic force.

The configuration of an RF card equipped with a radio frequency tag to which such a radio identification system is applied is typically an RF interface unit and a command detector that converts data into RF signals for data communication with a wireless antenna or a terminal (reader). The RF interface unit includes a rectifier for rectifying the induced voltage induced in the wireless antenna, a modulator for modulating and demodulating data transmitted and received by the wireless antenna, a voltage stabilizer for supplying a stable voltage to each component of the tag, and It consists of a clock generator for clocking the operation controller.

In addition, the command detector is composed of an operation controller having a data serial-parallel mutual conversion circuit, a RAM, and a ROM, and the operation controller performs a function of processing information according to a stored command of the ROM. The memory section includes an EEPROM capable of electrically writing and deleting data.

However, the application field of the RF card equipped with the radio frequency tag is used as a payment means such as a credit card and a traffic card. As such, when the RF card is used as a payment method, the recognition distance between the terminal and the RF card is about several centimeters. By limiting, it prevents the misrecognition of other RF cards in the vicinity of the terminal installed.

To this end, the radio frequency band to be transmitted and received wirelessly uses a low frequency band of 13.56MHz.

Recently, however, various applications of RF cards equipped with such radio frequency tags have been provided. For example, they have been used to check attendance at universities.

At this time, when the attendance check, the recognition distance between the terminal and the RF card when contactless is provided so that the recognition distance is large, about a few meters to 10m, in order to prevent congestion caused when a large number of attendance checkers gather at the terminal during the attendance check.

To this end, the radio frequency band to be transmitted and received wirelessly uses a high frequency band of 900MHz.

As such, the RF card used for various purposes such as various authentication or payment means is separately provided as a card having different radio frequency bands of high frequency band and low frequency band according to each purpose. There is a problem in that each RF card mounted with a tag having a different radio frequency band must be individually carried.

The present invention is to solve the problems of the prior art, the purpose of the present invention is to mount each radio frequency tag having a different frequency band by using a single card, the traffic fare settlement, various automation projects, The present invention provides an RF card loaded with heterogeneous tags having different frequency bands that can be selectively used in various fields such as distribution, livestock management, access control, time and attendance management, logistics management, and parking management.

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

1 is a schematic block diagram showing an RF card equipped with a heterogeneous tag having a different frequency band of the present invention, Figure 2 is a detailed block diagram showing a tag for the low frequency band of the configuration of Figure 1, Figure 3 1 is a detailed block diagram illustrating a tag for a high frequency band, and FIG. 4 is a schematic system diagram showing each terminal having a different frequency band from an RF card equipped with a heterogeneous tag having a different frequency band. .

As shown, the RF card equipped with a heterogeneous tag having a different frequency band of the present invention is a card 100, a tag for the low frequency band 200 is mounted on one side of the card 100, and the card It consists of a high frequency band tag 300 mounted on the other side of the (100).

The low frequency band tag 200 uses a 13.56 MHz radio frequency band, and is provided with a coil loop antenna 210 installed along a circumference of the low frequency band tag 200 and a low frequency through the coil loop antenna 210. Low-frequency RF interface 220 for converting the radio transmission and reception-related transmission data processed for the wireless terminal and the band terminal 400 to the low-frequency RF transmission signal, and the extraction, writing, and deletion of the stored information is possible The memory unit 230 stores wireless transmission / reception related transmission data and a command detector 240 for processing the wireless transmission / reception related transmission data stored in the memory unit 230 according to the stored command.

In addition, the high frequency band tag 300 uses a 900 MHz radio frequency band, a dipole antenna 310, a memory unit 320 storing radio transmission and reception related transmission data, and the dipole antenna. High frequency RF interface unit for extracting the radio transmission and reception related transmission data stored in the memory unit 320 and processing the high frequency RF transmission signal so as to communicate with the high frequency band terminal 500 through the 310 ( 330).

Heterogeneous tags (200,300) mounted on the card 100 are divided into a coil loop antenna 210 and a dipole antenna 310, respectively, which is installed, which is a low frequency band terminal 400 or a high frequency band terminal 400,500. It is possible to distinguish and recognize the low frequency band RF information request signal or the high frequency band RF information request signal transmitted wirelessly from different types, thereby preventing misunderstanding due to the RF information request signals for different frequency bands received between different tags 200 and 300. To do this.

That is, the coil loop antenna 210 is an RFID technology in which a magnetic coupling method is applied, and power energy and data transmission are transmitted by magnetic field energy formed by electric current. In more detail, the power energy generated by the antenna of the low frequency band terminal 400 by the driving current forms a magnetic field, and when the card 100 is located in the formed magnetic field region, the card 100 is mounted on the card 100. Among the heterogeneous tags 200 and 300, the low frequency band tag 200 is induced with a current in the coil loop antenna 210 due to a change in the magnetic field to generate a voltage.

Accordingly, the low frequency band tag 200 receives the minimum power required for wireless transmission of data from the low frequency band terminal 400. In this case, since the minimum power supplied from the low frequency band terminal 400 is a weak current, wireless transmission and reception of data is possible only at a very close distance, so that the recognition distance between the low frequency band terminal 400 and the low frequency band tag 200 may be several. It is limited to within cm.

In addition, the dipole antenna 310 is an RFID technology to which an electric coupling method is applied, and the high frequency band tag 300 reflects the microwave electromagnetic field signal wirelessly transmitted from the high frequency band terminal 500, and the reflected signal. In this case, the high frequency band terminal 500 uses the radar principle of wireless reception. At this time, the radio frequency of the radio signal is very high frequency (UHF; Ultra High Frequency) as the high frequency band terminal 500 and the high frequency band tag ( Since the recognition distance is long, the recognition distance is 300m, the card 100 having heterogeneous tags 200 and 300 is heterogeneous according to the positions of the low frequency band terminal 400 and the high frequency band terminal 400 and 500. Each tag 200 and 300 may receive a signal that is selectively wirelessly transmitted.

In addition, the low frequency RF interface unit 220 and the high frequency RF interface unit 330 which are separately mounted on the heterogeneous tags 200 and 300 mounted on the card 100 are typically inputted from the respective antennas 210 and 310. Rectifier for rectifying voltage, modulator for modulating and demodulating data transmitted / received, voltage stabilizer for supplying stable voltage to each tag (200, 300), and clock generator for clocking of operation controller are selectively configured. Since the modulation and demodulation schemes of the data modulated by the respective demodulators mounted on the units 220 and 330 are different from each other, even if a low frequency RF signal or a high frequency RF signal is input from each of the terminals 400 and 500, the respective low frequency RF interface units The RF transmission signal selectively transmitted by the 220 and the high frequency RF interface unit 330 is demodulated to one card 100. Even if the tag (200 300) to be mounted can be prevented which may be caused in the misrecognized each tag (200 300) in advance.

The command detector 240 mounted on the low frequency band tag 200 is typically composed of an operation controller having a data serial / parallel inter-conversion circuit, a RAM, and a ROM, and the operation controller may provide information according to a stored command of the ROM. Perform the function of processing.

Each of the memory units 230 and 320 mounted in the heterogeneous tags 200 and 300 may use an EEPROM capable of electrically writing and deleting data.

As an example, the function of the present invention configured as described above is mounted as an example. The low frequency band 13.56MHz uses the low frequency band tag 200, which is used as a payment method when using public transportation, and the high frequency band 900MHz, using the high frequency band used for attendance check when attending school lectures. If you want to go to school using the card 100 is equipped with a tag for each 300, first, the user can pay the public transportation fee using the card 100 of the present invention.

In other words, when the user wants to use the bus as a public transport, when the bus is getting on and off, the card 100 of the present invention is approached to the low frequency band terminal 200, which is a reader installed on the bus, by several centimeters, and the low frequency band by the driving current. Due to the change in the magnetic field generated from the coil loop antenna installed in the terminal 400, a current flows into the coil loop antenna 210 of the low frequency band tag 200 among the different tags 200 and 300 mounted on the card 100. The induced current is supplied to the low frequency RF interface 220 by the induced current.

When the low frequency RF interface unit 220 rectifies and stabilizes the supplied current to supply the command detector 240, the command detector 240 transmits radio transmission / reception related transmission data (postpaid) stored in the memory unit 230 according to a stored command. The user's authentication information and payment information of the public transportation fee at the time of payment, and the public transportation fee payment information consisting of the transportation fee balance information at the time of prepaid payment), and the processed radio transmission / reception related transmission data is processed for the low frequency RF interface. Forward to 220.

The low frequency RF interface unit 220 converts the transmitted radio transmission and reception related transmission data into a low frequency RF transmission signal and transmits the result to the coil loop antenna 210. The coil loop antenna 210 transmits the corresponding low frequency RF transmission signal. Public charges are performed by wireless transmission to the low frequency band terminal 400.

Here, the high frequency band tag 300, which is another tag mounted on the user's card 100, is different from the coil loop antenna 210 installed in the low frequency band tag 200 in the current reception method of the installed dipole antenna 310. Therefore, it does not receive the transmitted current and thus prevents misunderstanding.

In addition, when a user enters a lecture room when attending a lecture, the lecture room is equipped with a high-frequency band terminal 500 as a reader, and the tag for the high-frequency band mounted on the card 100 possessed by the user at a distance of a few meters away. A microwave electromagnetic signal, which is a high frequency RF transmission signal, is transmitted to the dipole antenna 310 of 300.

The dipole antenna 310 receives the transmitted microwave electromagnetic field signal and supplies it to the high frequency RF interface unit 330.

The high frequency RF interface unit 330 rectifies and stabilizes the supplied microwave electromagnetic field signal, processes the radio transmission and reception related transmission data (including user authentication information) stored in the memory unit 230, and processes the processed radio transmission and reception. The relevant transmission data is transmitted to the high frequency RF interface unit 330.

The high frequency RF interface unit 330 converts the transmitted radio transmission and reception related transmission data into a high frequency RF transmission signal and then transmits the result to the dipole antenna 310, and the dipole antenna 310 transmits the corresponding high frequency RF transmission signal to a high frequency band. By wireless transmission to the terminal 500 confirms the attendance participation of the user.

In addition, the high-frequency band tag 300 can simultaneously recognize dozens to hundreds of tags per second, so there is no need to recognize them individually like the recognition method of the low-frequency tag 200, and multiple recognition is possible so that several people enter the classroom. If you do, bottlenecks do not occur and you can effectively check attendance.

As described above, RF cards equipped with heterogeneous tags having different frequency bands include various automation projects, distribution businesses, livestock management, access control, time and attendance management, logistics management, parking management, etc. together with the above-mentioned transportation fee payment and attendance check. It can be applied to industry.

As described above, the present invention is equipped with each radio frequency tag having a different frequency band by using a single RF card, traffic charges having different frequency bands, various automation projects, distribution businesses, livestock management, access control, It shows the effect that can be mixed and used selectively among various fields such as time and attendance management, logistics management and parking management.

1 is a schematic configuration diagram showing an RF card equipped with heterogeneous tags having different frequency bands of the present invention;

FIG. 2 is a detailed block diagram illustrating a tag for a low frequency band in the configuration of FIG. 1; FIG.

3 is a detailed block diagram illustrating a tag for a high frequency band in the configuration of FIG. 1;

4 is a schematic system configuration diagram showing respective terminals having different frequency bands from RF cards equipped with heterogeneous tags having different frequency bands of the present invention.

<Code Description of Main Parts of Drawing>

100: card 200: tag for the low frequency band

210: coil loop antenna 220: RF interface for low frequency

230: memory unit 240: command detector

300: Tag for high frequency band 310: Dipole antenna

320: memory unit 330: RF interface unit for high frequency

400: terminal for low frequency band 500: terminal for high frequency band

Claims (3)

Card 100, Low frequency band tag 200 mounted on one side of the card 100, RF card equipped with a heterogeneous tag having a different frequency band, characterized in that consisting of a high-frequency band tag 300 mounted on the other side of the card (100). The method of claim 1, The low frequency band tag 200 uses a radio frequency band of 13.56 MHz band, A coil loop antenna 210 installed along a circumference of the low frequency band tag 200; A low frequency RF interface unit 220 for converting the radio transmission / reception related transmission data, which is processed to perform wireless data communication with the low frequency band terminal 400 through the coil loop antenna 210, to a low frequency RF transmission signal; A memory unit 230 capable of extracting, writing, and deleting stored information and storing transmission data related to wireless transmission and reception; RF card equipped with a heterogeneous tag having a different frequency band, characterized in that consisting of a command detector 240 for processing the radio transmission and reception related transmission data stored in the memory unit 230 according to the stored instructions. The method according to claim 1 or 2, The high frequency band tag 300 uses a radio frequency band of 900 MHz band, A dipole antenna 310, A memory unit 320 storing wireless transmission / reception related transmission data; High-frequency RF for extracting the radio transmission and reception-related transmission data stored in the memory unit 320 to the high-frequency band terminal 500 and the wireless data communication through the dipole antenna 310 and processing into a high-frequency RF transmission signal RF card equipped with a heterogeneous tag having a different frequency band, characterized in that consisting of the interface unit 330.