KR20040032225A - Transponder - Google Patents

Abstract

PURPOSE: A transponder is provided to configure many RFID(Radio Frequency Identification) chips in the one transponder, thereby enabling the one transponder to exchange information with many readers. CONSTITUTION: Capacitors(60a,60b,60n) are connected to capacitors(62a) in parallel to have bigger resonant frequency values than a specific resonant frequency. A capacitor(60c) is connected to one of the capacitors(62a) in serial so as to have a smaller resonant frequency value than the specific resonant frequency. RFID chips(602a,602b,602c,.....602n) installed on a transponder react to all readers having the specific resonant frequency, and exchange information with all the reacted readers.

Description

Transponders

The present invention relates to a transponder, and more particularly, by configuring a plurality of radio frequency identification chips in one transponder, one transponder can exchange information with a plurality of readers. It is to make it possible.

In general, automatic identification includes a contact method and a contactless method. In the RFID method, a contactless recognition method, information is exchanged by mutual induction between a transponder and a reader. An automatic RFID recognition method will be described with reference to FIG. 1.

The reader 10 includes an LC circuit in which a leader coil 101 having an inductance L ₁ and a capacitor 102 having a capacitance C ₁ is connected in series, and the transponder 20 has an antenna coil 103 having an inductance L ₂ . And a parallel LC circuit composed of a capacitor 104 having a capacitance C ₂ and an integrated circuit (IC) 105 connected in parallel thereto.

The operation of the RFID method having the above configuration is as follows. First, when the transponder 20 is brought closer to the reader 10, the antenna coil 103 of the transponder 20 is driven by the alternating current I ₁ flowing through the reader 10. 101 generates induced electromotive force. That is, a current caused by induced electromotive force flows in the transponder 20, and this current becomes an operating current for the transponder 20 to operate. In addition, the antenna coil 103 of the transponder 20 and the capacitor 104 having a capacitance C _{2 form} a parallel LC circuit. At this time, the parallel LC circuit formed by the antenna coil 103 of the transponder 20 and the capacitor 104 having the capacitance C ₂ causes electrical vibration due to the generation of induced electromotive force. In this case, since the current I ₂ flowing to the integrated circuit 105 is maximized, an operating current sufficient for the integrated circuit 105 to operate may be applied to the integrated circuit 105. That is, the transponder 20 is operated by the power induced by the reader 10 instead of its own power. Such a type is called a passive type.

Meanwhile, information is also transmitted through the reader 10 in addition to power. The information transmitted from the reader 10 to the transponder 20 will be described with reference to FIG. do. The serial resonant circuit of the reader 10 sequentially transmits information to the transponder 20 by repetitively repeating a predetermined time (10 clocks) and resonating (5 clocks) when no resonance occurs. . In this case, as shown in the detailed block diagram of the transponder shown in FIG. 3, information and power are transferred to the integrated circuit of the transponder 20, and the integrated circuit operates accordingly, and the clock is performed. By checking and extracting information (clock extraction), the information given by the reader 10 is also obtained. The memory or the CPU 301 included in the integrated circuit by the information transmitted as described above intercepts the switch 303 according to the information clock transmitted from the reader 10 through the modulator 302. Meanwhile, the serial resonant circuit of the reader 10 has a continuous resonance state in order to receive information from the transponder 20 after transmitting information to the transponder 20. In this case, when the switch 303 of the integrated circuit is open, the oscillation is performed at amplitude A as shown in FIG. 4, and when the switch 303 is connected, the leader coil 101 and the antenna coil 103 are separated. The oscillation causes the amplitude B to be reduced, resulting in a change in amplitude D. As a result, the reader 10 reads the information transmitted by the transponder 20. Fig. 5 shows a conventional transponder mounted on a card or the like, which is composed of an antenna coil 103 and an RFID chip 502. Of course, the RFID chip 502 is composed of a capacitor 104 and an integrated circuit 105 forming a parallel resonant circuit with the antenna coil 103.

On the other hand, the company that distributes the transponders such as banks or credit card companies that require cash payments mainly by the card, the transponders are distributed in the form of mounting on the card or portable devices, etc. In particular, it is mainly used in the card used as a transportation card.

However, according to a number of companies that distribute transponders, information that transponders and readers can extract and extract and integrated circuits for calculating information corresponding to the extracted information are different from each other. The resonant frequency used is 13.56MHz, and the capacitor included in the RFID chip has a capacitance value between 20pF and 100pF, depending on the company producing it. Since a transponder having an RFID chip is used, an antenna coil suitable for an arbitrary capacitance of the capacitor is required for the LC circuit of the transponder to resonate. Therefore, a user who has a large number of trading companies has a inconvenience in that they have to carry all the transponders distributed by a plurality of counterparties for cash payment by RFID method. In addition, when the user keeps close proximity to the reader that does not want to exchange information, there was a problem that a transponder that does not want to use can be used.

The present invention has been made to solve the above problems, and an object of the present invention is to provide a transponder capable of exchanging information with a plurality of readers by one transponder.

1 is a block diagram of a general RFID scheme.

2 is a graph of signals in the case of sending power and information from a reader to a transponder.

3 is a detailed block diagram of a general transponder.

4 is a graph of information input to a reader from a transponder.

5 is a schematic diagram of a conventional transponder.

6 is a block diagram of a transponder according to an embodiment of the present invention.

7 is a block diagram of a transponder according to another embodiment of the present invention.

8 is a schematic diagram of the transponder of FIG.

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

600: transponder 601: antenna coil

602a to 602n: RFID chip 603: switching means

60a to 60n: capacitor A 61a to 61n: integrated circuit

62a to 62n: capacitor B

Transponders according to the present invention for achieving the above object, n (n) each containing one antenna coil having a constant inductance (L) and a capacitor A constituting the antenna coil and the resonance circuit And 2) switching means for selectively switching the n RFID chips and the n RFID chips to the antenna coil.

In addition to the above, the mobile phone terminal, PDA terminal, portable computer, MP3 player, credit card, cash card, traffic card, identification card according to the present invention is characterized in that the transponder is mounted.

Hereinafter, overlapping components will be denoted by the same reference numerals, and duplicated or omitted components and operations, which will overlap with the prior art, will be described in detail with reference to the accompanying drawings.

6 is a block diagram showing a transponder according to a first embodiment of the present invention.

The transponder 600 according to the present embodiment interacts with the reader coil to produce power for the operation of the RFID chip, and receives information transmitted from the reader.

The new unit is connected to the antenna coil 601 having an inductance L and the antenna coil 601 in parallel. 2) RFID chips 602a, 602b, ..... 602n are provided, and these n RFID chips 602a, 602b, ..... 602n are also connected in parallel with each other. Meanwhile, switching means 603 is provided to selectively switch the n RFID chips 602a, 602b,..., 602n to the antenna coil 601. On the other hand, the n RFID chips 602a, 602b, ....., 602n each have a capacitor A having a capacitance of C (60a, 60b, ..., 60n) and an integrated circuit (IC, 61a, 61b, ..., 61n), and the capacitors A (60a, 60b, ..., 60n) form a parallel LC circuit with the antenna coil (601). The LC circuit is configured to have a resonance frequency that matches a specific resonance frequency of the series LC resonant circuit configured in the reader. In general, the resonant frequency of the serial LC resonant circuit of the reader has any one of 125 KHz, 13.56 MHz, and 2.4 GHz, so that when the antenna coil 601 has a specific inductance L value, the capacitors 60a, 60b, ..., 60n) capacitance C is the formula for the resonance frequency (f ₀ ) It is provided to match the resonant frequency of the series LC circuit. This configuration is to ensure sufficient operating current for the integrated circuits 61a, 61b, ..., 61n to receive the information sent from the various readers and to calculate the corresponding information. At this time, the capacitor A of each of the n RFID chips 602a, 602b, ..... 602n has the same capacitance as C. Of course, the switching means may be provided as a manual changeover switch that is manually switched in order for a user to arbitrarily select one of the n RFID chips 602a, 602b, ....., 602n. It is preferable that either is provided as an automatic changeover switch which is automatically switched according to key input of a device (mobile phone terminal, MP3 player, portable computer) on which the fender 600 is mounted.

As a use case of the transponder according to the above configuration, first, a case in which the transponder 600 provided with a manual conversion switch is mounted on a traffic card will be described. In order to use transportation, users use payment by transportation card instead of cash payment, which has a leader that sends out different information to each of the companies that provide transportation. A transponder equipped with n RFID chips which can be provided is provided in the traffic card. The user switches among the n RFID chips that can receive information from a reader installed by a company that provides a means of transportation for the purpose of payment or to calculate the corresponding information. By operating the means 603 it is connected to the antenna coil 601. As a result, the traffic card exchanges information with the reader and the card payment is made accordingly. Next, a case in which a transponder 600 equipped with an automatic switching switch which is automatically switched by a key input of a device on which the transponder 600 is mounted is mounted will be described. If the user wants to use the transportation provided by a specific company, he selects the RFID chip he wants to select from the button of his mobile phone terminal to select the RFID chip that can be reacted by the reader installed by the company. Selecting and pressing a button to be marked is connected to the antenna coil and the RFID chip to be selected by the self, so that the transponder and reader mounted on the mobile phone can replace the cash payment. Of course, a mobile phone terminal can also be equipped with a transponder having a manual changeover switch that is switched by a user's manual selection.

However, in the first embodiment having the above configuration, as described in the related art, the serial LC of the reader is because the capacitance of the capacitor A included in the RFID chip has a value within the range of 20 pF to 100 pF for each company producing the RFID chip. The resonant frequency of the circuit and the resonant frequency of the parallel LC circuit of the transponder may be inconsistent, and thus, it is difficult to provide a transponder capable of reacting with a wider variety of readers. Therefore, to solve this problem, a second embodiment as shown in FIG. 7 has been proposed.

In FIG. 7, the capacitors A (60a, 60b, 60c, ..., 60n) included in the n RFID chips provided in the transponder 600, respectively, have capacitances of C ₁ , C ₂ , C _{3, ... ...} are all different with C _n . In this case, if n RFID chips are directly connected to one antenna coil 601 by being switched by switching means, the capacitors A (60a, 60b, 60c, ..., 60n) included in each RFID chip and the The resonance frequency due to the antenna coil 601 is a formula All of them will have different resonant frequency values. In general, a resonant frequency of 13.56 MHz is used for a serial resonant circuit of a reader and a parallel resonant circuit of a transponder. In this case, an RFID chip other than an RFID chip having a capacitor whose resonance frequency of the antenna coil 601 is 13.56 MHz is used. Is not needed. Therefore, as shown in FIG. 7, the capacitor A ₁ (60a) and the capacitor A ₂ (resonance frequency) having a resonance frequency value larger than a specific resonance frequency (f _0, for example, 13.56 MHz) by the formula for f ₀ above. 60b), capacitor A _n (60n) is connected in parallel to capacitor B ₁ (62a), capacitor B ₂ (62a), capacitor B ₃ (62a) to have the specific resonance frequency (f ₀ ) value, Capacitor B ₃ (62a) is connected in series to the capacitor A ₃ (60c) having a resonant frequency value smaller than the specific resonant frequency (f ₀ ) to have the specific resonant frequency (f ₀ ). In this case, the n RFID chips 602a, 602b, 602c, ..., and 602n provided in the transponder can exchange information by reacting with a plurality of different readers having a specific resonance frequency f ₀ . do. Of course, the capacitor B _Y is not necessary in the above. If the capacitor A _X of the RFID chip and the LC circuit formed by the antenna 601 have a specific resonance frequency (f ₀ ), the capacitor B _Y is in series. Or there is no need for a parallel connection. 8 schematically illustrates the transponder of FIG.

The transponder according to the present invention described above can be mounted on all articles that can be used for contactless information exchange, in particular, portable articles. That is, preferred examples include a mobile phone terminal, a PDA terminal, a portable computer, an MP3 player, a credit card, a cash card, a traffic card, an identification card, and the like.

In addition to those described above, those skilled in the art may easily implement the present invention in other forms within the same scope as described above only by the description of the present invention.

As described in detail above, the transponder according to the present invention can react for information exchange with a plurality of readers, and when such a transponder is mounted on various cards, it is possible to replace various types of cards by one card. The convenience of holding a card increases, and the cost of issuing the card also decreases. On the other hand, even when the transponder according to the present invention is mounted on a variety of portable devices, by owning a single portable device, it is possible to relate to a company that provides a variety of services such as transportation services, banking services, etc. in place of cash payments, and types of services There is a convenience that can be used at any time without.

On the other hand, since the RFID chip which is not intended to be used is opened by the switching means, there is also an effect that can prevent the unintended use of the RFID chip which is not desired by the user even when located close to the reader.

Claims (12)

N (n) which includes one antenna coil having a specific inductance L and a capacitor A constituting the LC coil and the antenna coil. 2) a transponder comprising switching means for selectively switching the RFID chips and the n RFID chips to the antenna coil. The method of claim 1, The capacitance (C) values of the n capacitors A included in the n RFID chips, respectively, are the same, so that a specific resonance frequency is obtained even when the n RFID chips are selectively switched to the antenna coil by the switching means. and a (f ₀ ) transponder. The method of claim 1, Capacitor C of any one or more capacitors A _X of the n capacitors A included in the n RFID chips are different, and capacitor B _Y is connected to the RFID chip including this capacitor A _X , thereby providing the n capacitors A. In all cases where is selectively switched to the antenna coil by the switching means And the LC circuit of the antenna coil and the capacitor A _X and the capacitor B _Y has a specific resonance frequency (f ₀ ). The method of claim 4, wherein The capacitor B _Y is connected in series with the capacitor A _X when the resonance frequency of the resonance circuit formed by the antenna coil and the capacitor A _X of the RFID chip is smaller than a specific resonance frequency f ₀ . And the resonant frequency of the resonant circuit formed by the capacitor A _X of the RFID chip is connected in parallel to the capacitor A _X when the resonant frequency of the resonant circuit of the RFID chip is greater than a specific resonant frequency (f ₀ ). The method according to claim 2 or 4, The specific resonant frequency (f ₀ ) is a transponder, characterized in that any one of 125KHz, 13.56MHz, 2.4GHz. The method of claim 1, The switching means is a transponder, characterized in that the manual switching switch. The method of claim 1, And said switching means is an automatic changeover switch which is automatically switched by a command input by a key input means of a device on which said transponder is mounted. A mobile phone terminal or a PDA terminal, characterized in that the transponder of claim 1 is mounted. A portable computer, characterized in that the transponder of claim 1 is mounted. MP3 player, characterized in that the transponder of claim 1 is mounted A credit card or cash card or transportation card, characterized in that the transponder of claim 1 is mounted. Identification card, characterized in that the transponder of claim 1 is mounted.