JP2012068932A - Non-contact type ic card - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a non-contact type IC card in which multiple types of non-contact type IC card functions such as a TYPE-A, TYPE-B, and FeliCa(TM) can be installed.SOLUTION: A pulse counter 24 counts the wave number (number of amplitudes) of carrier waves within a fixed sampling period measured by a sampling timer 25. Based on this count value, it is determined whether the frequency of the received carrier waves are consistent with carrier waves used for communication in a TYPE-A module 30-1, a TYPE-B module 30-2, and a FeliCa(TM) module 30-3. When they are consistent, a CPU 29 controls a TYPE-A module 30-1, a TYPE-B module 30-2, and a FeliCa(TM) module 30-3 to sequentially start, and controls one of the modules in which analysis error in the received data is not generated in the initial response operation to be activated selectively.

Description

  The present invention relates to a non-contact type IC card, and more particularly to a non-contact type IC card that enables a plurality of types of non-contact type card functions to be contained in a single card.

  As IC cards incorporating an integrated circuit (IC) for performing calculations, contact type IC cards and non-contact type IC cards are known.

  Here, the non-contact type IC card transmits a carrier wave from the reader / writer, supplies power to the IC card by electromagnetic induction, and communicates between the reader / writer and the card by modulating the carrier wave. There are three types of contactless IC cards that use 13.56 MHz as the frequency of the carrier wave: TYPE-A, TYPE-B standardized by ISO / IEC 14443, and FeliCa (trademark) developed by Sony Corporation. Are known.

  TYPE-A employs a communication speed of 106 Kbps, a modulation method of 100% ASK (amplitude shift keying), and a mirror and Manchester encoding method.

  TYPE-B employs a communication speed of 106 Kbps, a modulation scheme of 10% ASK (amplitude shift keying), and a coding scheme of NRZ (non-return-to-zero).

  In addition, FeliCa (trademark) employs a communication speed of 212 Kbps, a modulation scheme of 10% ASK (amplitude shift keying), and a coding scheme of Manchester.

  As described above, the three types of non-contact type IC cards have different communication speeds, modulation methods, and encoding methods. Therefore, the three types of non-contact type IC cards of TYPE-A, TYPE-B, and FeliCa (trademark) are used. When using an IC card, it is necessary to carry three types of cards corresponding to each standard.

  By the way, conventionally, as an IC card which tried to give a plurality of card functions to a single card, a single card provided with a plurality of contact type IC card functions, A contact IC card and one or more contact IC card functions are known.

  Moreover, what was described in patent document 1 is known as what provided the several non-contact-type IC card function to one card | curd.

JP 2007-287128 A

  However, the non-contact type IC card described in Patent Document 1 is provided with a plurality of non-contact IC cards having different frequencies of carriers used for communication by mounting a plurality of pairs of RF modules and IC card modules on one card. A contact IC card function is realized, and the carrier wave frequency is the same, but the communication speed, the modulation method, and the coding method are different, for example, TYPE-A, TYPE-B, and FeliCa (trademark) 3 There is no conventional one that realizes a non-contact type IC card function with a single card.

  Therefore, the present invention provides a non-contact type IC card that can accommodate a plurality of types of non-contact type IC card functions such as TYPE-A, TYPE-B, and FeliCa (trademark) in one card. For the purpose.

  In order to achieve the above object, the invention of claim 1 is a non-contact type that is driven by electric power generated by electromagnetic induction of a carrier wave conveyed from a reader / writer and communicates with the reader / writer by modulation of the carrier wave. Type IC card, the frequency of the carrier wave used for the communication is the same, but a plurality of card processing circuits having different communication speeds, modulation methods, and encoding methods, and carrier waves used by the plurality of card processing circuits are transmitted and received Possible radio circuit, frequency detection means for detecting the frequency of the carrier wave received from the reader / writer by the radio circuit, and the frequency detected by the frequency detection means is the frequency of the carrier wave used in the plurality of card processing circuits If they coincide with each other, the activation control means for sequentially starting the plurality of card processing circuits and each card by the sequential activation by the activation control means. Determining means for determining whether or not a received data analysis error occurs in an initial response operation in the processing circuit; and an activity for selectively controlling the card processing circuit in which the received data analysis error does not occur in the determining means to an active state Control means.

  According to a second aspect of the present invention, in the first aspect of the invention, the wireless circuit includes a plurality of modulation / demodulation circuits respectively corresponding to the plurality of card processing circuits, and the activation control means in the plurality of modulation / demodulation circuits, The modulation / demodulation of the carrier wave is performed using a modulation / demodulation circuit corresponding to the card processing circuit activated or activated by the activation means.

  According to a third aspect of the present invention, in the first aspect of the invention, the frequency detection unit analog-digital converts a carrier wave from the reader / writer received by the wireless circuit and outputs a pulse signal; and When the amplitude of the carrier wave is stable, a switch circuit that is turned on to pass a pulse signal output from the analog-digital conversion circuit, a sampling timer that starts measuring a predetermined sampling time by turning on the switch circuit, A pulse counter that counts pulses of the pulse signal output from the analog-digital conversion circuit that has passed through the switch circuit during the time measured by the sampling timer, and the frequency of the carrier wave based on the count data of the pulse counter Is detected.

According to the present invention,
(1) Although the frequency of the carrier wave used for communication is the same, a plurality of types of contactless card functions having different communication speeds, modulation schemes, and encoding schemes can be stored in one card. There is no need to carry various types of non-contact type IC cards. (2) Three types of non-contact type IC card functions of TYPE-A, TYPE-B, and FeliCa (trademark) can be realized with one card. There are effects such as.

FIG. 1 is a block diagram showing a configuration of a non-contact type IC card according to the present invention. FIG. 2 is a block diagram showing a detailed configuration of the RF module of the non-contact type IC card shown in FIG. FIG. 3 is a waveform diagram for explaining the operation of the non-contact type IC card shown in FIG. FIG. 4 is a flowchart for explaining processing of the non-contact type IC card shown in FIG. FIG. 5 is a block diagram showing another configuration of the non-contact type IC card according to the present invention.

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

  FIG. 1 is a block diagram showing a configuration of a non-contact type IC card according to the present invention.

  In the non-contact type IC card according to the present invention, three types of non-contact type IC card functions of TYPE-A, TYPE-B, and FeliCa (trademark) are realized with one card.

  The non-contact type IC card shown in FIG. 1 includes a TYPE-A module 30-1 and a TYPE- for realizing three types of non-contact type IC card functions of TYPE-A, TYPE-B, and FeliCa (trademark). Three card processing circuits of B module 30-2 and FeliCa (trademark) module 30-3 are mounted.

  The non-contact type IC card shown in FIG. 1 uses a pulse counter 24 to count the wave number (amplitude number) of a carrier wave within a certain period measured by a sampling timer 25, for example, a sampling period of 1 ms, and based on this count value, a received carrier wave Are matched with the 13.56 MHz carrier used for communication in the TYPE-A module 30-1, the TYPE-B module 30-2, and the FeliCa ™ module 30-3. -A module 30-1, TYPE-B module 30-2, and FeliCa (trademark) module 30-3 are sequentially activated under the control of the CPU 29, and a module that does not cause an analysis error of received data in its initial response operation is selectively selected. Control to the active state.

  The RF module 10 includes an induction power supply unit 11 that receives a carrier wave from a card reader / writer (not shown) and generates electric power by electromagnetic induction of the carrier wave. The RF module 10 transmits / receives a carrier wave digitally modulated by ASK modulation or the like to a corresponding card reader / writer (not shown).

  Here, since the RF module 10 transmits and receives carrier waves used in each of the TYPE-A module 30-1, the TYPE-B module 30-2, and the FeliCa (trademark) module 30-3, the TYPE-A module 30- 1. A 13.56 MHz carrier wave used for communication is transmitted and received in the TYPE-B module 30-2 and the FeliCa (trademark) module 30-3.

  A detailed configuration of the RF module 10 shown in FIG. 1 is shown in FIG. In addition to the induction power supply unit 11, the RF module 10 includes an antenna 1, a reception unit 2, a transmission unit 3, a carrier wave separation circuit 4, a TYPE-A digital demodulation unit 5-1, and a TYPE-B digital demodulation unit 5. -2, FeliCa (trademark) digital demodulator 5-3, and received data extractor 6.

  In this RF module 10, communication is performed with a corresponding card reader / writer (not shown) using digital modulation of a carrier wave of 13.56 MHz, that is, ASK (amplitude shift keying), so the TYPE-A module 30- 1 to perform communication using the TYPE-A digital demodulation unit 5-1, digitally demodulate the received carrier wave to extract received data, and to perform communication using the TYPE-B module 30-2. When the received carrier wave is digitally demodulated by the -B digital demodulator 5-2 to extract received data and communication is performed using the FeliCa (trademark) module 30-3, the digital demodulator for FeliCa (trademark) 5-3 Then, the received carrier wave is digitally demodulated to extract the received data.

  The transmitting unit 3 includes modulation circuits corresponding to the TYPE-A module 30-1, the TYPE-B module 30-2, and the FeliCa (trademark) module 30-3, and uses the TYPE-A module 30-1. When communicating with the TYPE-A module 30-1, the carrier wave is modulated with the received data by the modulation method corresponding to the TYPE-A module 30-1, and when communicating with the TYPE-B module 30-2, the TYPE-B module 30- In the case where communication is performed using the FeliCa (trademark) module 30-3, the carrier wave is received by the modulation scheme corresponding to the FeliCa (trademark) module 30-3. Modulate with.

  The reception data extraction unit 6 is controlled by the CPU 29 from the outputs of the TYPE-A digital demodulation unit 5-1, the TYPE-B digital demodulation unit 5-2, and the FeliCa (trademark) digital demodulation unit 5-3. , The received data corresponding to one of the TYPE-A module 30-1, the TYPE-B module 30-2, and the FeliCa (trademark) module 30-3 that is controlled to be activated or active is extracted.

  When the RF module 10 receives a carrier wave with the antenna 1, the induction power supply unit 11 generates power by electromagnetic induction of the carrier wave. The electric power generated by the induction power supply unit 11 is supplied to each part of the non-contact type IC card and drives the crystal oscillator 21 that generates a clock signal for driving the CPU 29.

  The carrier wave received by the antenna 1 of the RF module 10 is received by the receiving unit 2, and the carrier wave is separated by the carrier wave separation circuit 4. The carrier wave separated by the carrier wave separation circuit 4 is output to the A / D conversion circuit 22 in FIG. 1, where it is converted into a pulse signal for counting the wave number of the carrier wave.

  When the amplitude of the carrier wave received by the RF module 10 is stabilized, the induction power supply unit 11 outputs a power detection signal. This power detection signal is applied to a switch circuit 23 that opens and closes a pulse signal output from the A / D conversion circuit 22. The switch circuit 23 is opened (ON) by this power detection signal, passes the pulse signal output from the A / D conversion circuit 22, and is applied to the pulse counter 24.

  When the switch circuit 23 is opened, the output of the switch circuit 23 starts a sampling timer 25 that measures a certain sampling period.

  The pulse counter 24 counts the number of pulses of the pulse signal output from the A / D conversion circuit 22 within the sampling period counted by the sampling timer 25 under the control of the CPU 29.

  The sampling count data table 28 includes a fixed sampling period corresponding to the carrier frequency used in the TYPE-A module 30-1, the TYPE-B module 30-2, and the FeliCa ™ module 30-3, that is, 13.56 MHz. Sampling count data corresponding to the wave number count data is stored.

  The CPU 29 compares the count data of the pulse counter 24 with the sampling count data stored in advance in the sampling count data table 28, and the frequency of the carrier wave received by the RF module 10 is determined as the TYPE-A module 30-1, TYPE. -It determines whether it corresponds to the frequency of the carrier wave used by B module 30-2 and FeliCa (trademark) module 30-3, ie, 13.56 MHz.

  It is determined that the frequency of the carrier wave received by the RF module 10 corresponds to the frequency of the carrier wave used in the TYPE-A module 30-1, the TYPE-B module 30-2, and the FeliCa ™ module 30-3, that is, 13.56 MHz. In this case, the CPU 29 determines which one of the TYPE-A module 30-1, the TYPE-B module 30-2, and the FeliCa (trademark) module 30-3 the card reader / writer that has received the carrier wave corresponds to. In order to make a determination, the TYPE-A module 30-1, the TYPE-B module 30-2, and the FeliCa ™ module 30-3 are sequentially activated.

  The TYPE-A module 30-1, the TYPE-B module 30-2, and the FeliCa ™ module 30-3 are sequentially activated by chip select signals CS1, CS2, and CS3 output from the CPU 29.

  That is, first, the chip select signal CS1 is turned on, and the chip select signals CS2 and CS3 are turned off.

  At this time, the reception data extraction unit 6 shown in FIG. 2 of the RF module 10 extracts reception data corresponding to the TYPE-A module 30-1 output from the TYPE-A digital demodulation unit 5-1 under the control of the CPU 29. Then, the extracted reception data is received by the reception circuit 26, stored in the memory 26, and directly transmitted to the CPU 29.

  The CPU 29 transmits the reception data corresponding to the TYPE-A module 30-1 to the TYPE-A module 30-1, the TYPE-B module 30-2, and the FeliCa (trademark) module 30-3 by serial communication.

  Here, since only the chip select signal CS1 is ON, the reception data corresponding to the TYPE-A module 30-1 transmitted from the CPU 29 is received by the TYPE-A module 30-1.

  The TYPE-A module 30-1 starts an initial response operation upon reception of the received data corresponding to the TYPE-A module 30-1. Here, if no analysis error of the received data occurs, the TYPE-A module 30-1 receives the carrier wave. The corresponding card reader / writer (not shown) is assumed to be compatible with the TYPE-A module 30-1, and continues to hold the chip select signal CS1 to activate the TYPE-A module 30-1. I do.

  As a result, the non-contact type IC card performs communication with a card reader / writer (not shown) using the TYPE-A module 30-1.

  Transmission data from the TYPE-A module 30-1 to a card reader / writer (not shown) is output from the TYPE-A module 30-1 and added to the transmission unit 3 shown in FIG. The transmission unit 3 modulates the carrier wave with the transmission data by a modulation method corresponding to the TYPE-A module 30-1 and outputs the result from the antenna 1.

  If there is an analysis error of received data in the initial response operation in the TYPE-A module 30-1, the corresponding card reader / writer (not shown) that has received the carrier wave is not compatible with the TYPE-A module 30-1. Then, the chip select signal CS2 is turned on and the chip select signals CS1 and CS3 are turned off.

  At this time, the reception data extraction unit 6 shown in FIG. 2 of the RF module 10 extracts reception data corresponding to the TYPE-B module 30-2 output from the TYPE-B digital demodulation unit 5-2 under the control of the CPU 29. Then, the extracted reception data is received by the reception circuit 26, stored in the memory 27, and directly transmitted to the CPU 29.

  The CPU 29 transmits the reception data corresponding to the TYPE-B module 30-2 to the TYPE-A module 30-1, the TYPE-B module 30-2, and the FeliCa (trademark) module 30-3 by serial communication.

  Here, since only the chip select signal CS2 is ON, the reception data corresponding to the TYPE-B module 30-2 transmitted from the CPU 29 is received by the TYPE-B module 30-2.

  The TYPE-B module 30-2 starts an initial response operation upon reception of the reception data corresponding to the TYPE-B module 30-2. Here, if no analysis error of the reception data occurs, the TYPE-B module 30-2 receives the carrier wave. The corresponding card reader / writer (not shown) is assumed to be compatible with the TYPE-B module 30-2, and continues to hold the chip select signal CS2 and activate the TYPE-B module 30-2. I do.

  Thereby, this non-contact type IC card performs communication with a card reader / writer (not shown) using the TYPE-B module 30-2.

  Note that transmission data from the TYPE-B module 30-2 to a card reader / writer (not shown) is output from the TYPE-B module 30-2 and added to the transmission unit 3 shown in FIG. The transmission unit 3 modulates the carrier wave with the transmission data by a modulation method corresponding to the TYPE-B module 30-2, and outputs it from the antenna 1.

  If there is an analysis error of received data in the initial response operation in the TYPE-B module 30-2, the corresponding card reader / writer (not shown) that has received the carrier wave is not compatible with the TYPE-B module 30-2. Then, the chip select signal CS3 is turned on, and the chip select signals CS1 and CS2 are turned off.

  At this time, the reception data extraction unit 6 shown in FIG. 2 of the RF module 10 receives the reception data corresponding to the FeliCa ™ module 30-3 output from the FeliCa ™ digital demodulation unit 5-3 under the control of the CPU 29. The received data is received by the receiving circuit 26, stored in the memory 27 and transmitted to the CPU 29, and the received data corresponding to the TYPE-A module 30-1 received by the receiving circuit 26 is directly received. It transmits to CPU29.

  The CPU 29 transmits the reception data corresponding to the FeliCa ™ module 30-3 to the TYPE-A module 30-1, the TYPE-B module 30-2, and the FeliCa ™ module 30-3 by serial communication.

  Here, since only the chip select signal CS3 is ON, the reception data corresponding to the FeliCa ™ module 30-3 transmitted from the CPU 29 is received by the FeliCa ™ module 30-3.

  The FeliCa (trademark) module 30-3 starts the initial response operation upon reception of the reception data corresponding to the FeliCa (trademark) module 30-3. Here, if no analysis error occurs in the reception data, the carrier wave is generated. The received card reader / writer (not shown) that corresponds to the FeliCa ™ module 30-3 continues to hold the chip select signal CS3 in the ON state, and activates the FeliCa ™ module 30-3. Perform active state processing.

  Thereby, this non-contact type IC card performs communication with a card reader / writer (not shown) using the FeliCa (trademark) module 30-3.

  Note that transmission data from the FeliCa (trademark) module 30-3 to a card reader / writer (not shown) is output from the FeliCa (trademark) module 30-3 and added to the transmission unit 3 shown in FIG. The transmission unit 3 modulates the carrier wave with the transmission data by a modulation method corresponding to the FeliCa (trademark) module 30-3 and outputs the modulated carrier wave from the antenna 1.

  According to such a configuration, three types of non-contact type IC card functions of TYPE-A, TYPE-B, and FeliCa (trademark) can be realized with one card.

  Since the TYPE-A module 30-1, the TYPE-B module 30-2, and the FeliCa (trademark) module 30-3 can be configured in a well-known manner, detailed description thereof is omitted.

  FIG. 3 is a waveform diagram for explaining the operation of the non-contact type IC card shown in FIG. In FIG. 3, three types of carriers shown in FIGS. 3A, 3 </ b> C, and 3 </ b> E are shown as carriers received by the RF module 10. In the non-contact type IC card shown in FIG. 2, the pulse counter 24 counts the wave number (amplitude number) of the carrier wave within a certain sampling period timed by the sampling timer 25.

  For example, if the carrier wave received by the RF module 10 is as shown in FIG. 3A, the pulse counter 24 counts “16”, and the carrier wave received by the RF module 10 is as shown in FIG. The pulse counter 24 counts “32”, and when the carrier wave received by the RF module 10 is as shown in FIG. 3E, the pulse counter 24 counts “64”. Based on this count data, it is determined whether this carrier wave is a 13.56 MHz carrier wave used for communication in the TYPE-A module 30-1, the TYPE-B module 30-2, and the FeliCa (trademark) module 30-3.

  3B shows an ASK modulation component when the carrier wave received by the RF module 10 is as shown in FIG. 3A, and FIG. 3D shows the carrier wave received by the RF module 10. 3 (C) shows the ASK modulation component, and FIG. 3 (F) shows the ASK modulation component when the RF module 10 receives the carrier wave as shown in FIG. 3 (E).

  FIG. 4 is a flowchart for explaining processing of the non-contact type IC card shown in FIG.

  When this process is started and the RF module 10 receives a carrier wave (step 401), the crystal oscillator 21 is driven, and then it is checked whether the amplitude of the received carrier wave is stabilized (step 402). If it is determined that the amplitude of the carrier wave is not stable (NO in step 402), the process returns to step 402 and waits for the amplitude of the received carrier wave to become stable.

  If it is determined in step 402 that the amplitude of the received carrier wave is stable (YES in step 402), the switch circuit 23 is turned on (step 403), and the pulse output from the A / D conversion circuit 22 by the pulse counter 24 is set. The number of pulses of the signal is counted (step 404).

  Next, the count data of the pulse counter 24 and the sampling count data of the sampling count data table 28 are compared (step 405), and it is checked whether the frequency is applicable (step 406). Here, the frequency of the received carrier wave is not a corresponding frequency, that is, the count data of the pulse counter 24 and the sampling count data of the sampling count data table 28 do not match, and the TYPE-A module 30-1 and the TYPE-B module 30. -2, If it is determined that the frequency is not 13.56 MHz, which is the frequency of the carrier used in the FeliCa ™ module 30-3 (NO in step 406), the process returns to step 401.

  In step 406, the frequency of the received carrier wave is the corresponding frequency, that is, the count data of the pulse counter 24 matches the sampling count data of the sampling count data table 28, and the TYPE-A module 30-1, TYPE-B If it is determined that the frequency of the carrier wave used in the module 30-2 and the FeliCa (trademark) module 30-3 is 13.56 MHz (YES in step 406), first, the chip select signal CS1 is turned ON, and TYPE-A The module 30-1 is activated (step 407).

  Then, the initial response operation of the TYPE-A module 30-1 is started (step 408), and it is checked whether there is an analysis error of received data (step 409).

  If it is determined in step 409 that there is no analysis error of received data for the initial response operation of the TYPE-A module 30-1 (NO in step 409), the chip select signal CS1 is continuously held ON, and the TYPE-A module An active state process is performed to activate 30-1 (step 416), and the processing of this non-contact type IC card is terminated.

  If it is determined in step 409 that there is an analysis error of received data (YES in step 409), then the chip select signal CS2 is turned on and the TYPE-B module 30-2 is activated (step 410). .

  Then, the initial response operation of the TYPE-B module 30-2 is started (step 411), and it is checked whether there is an analysis error of received data (step 412).

  If it is determined in step 412 that there is no analysis error of the received data for the initial response operation of the TYPE-B module 30-2 (NO in step 412), the chip select signal CS2 is continuously held ON, and the TYPE-B module An active state process is performed to activate 30-2 (step 416), and the processing of this non-contact type IC card is completed.

  If it is determined in step 412 that there is an analysis error of received data (YES in step 412), then the chip select signal CS3 is turned on and the FeliCa ™ module 30-3 is activated (step 413). ).

  Then, the initial response operation of the FeliCa (trademark) module 30-3 is started (step 414), and it is checked whether there is an analysis error of the received data (step 415).

  If it is determined in step 415 that there is no received data analysis error in the initial response operation of the FeliCa ™ module 30-3 (NO in step 415), the chip select signal CS3 is continuously held ON, and the FeliCa ™ ) An active state process is performed to activate the module 30-3 (step 416), and the processing of this non-contact type IC card is completed.

  If it is determined in step 415 that there is an analysis error of the received data (YES in step 415), the processing of this non-contact type IC card is finished as it is.

  Although the above is an example of typical embodiment of this invention, this invention is not limited to the Example shown in the said Example and drawing, It can implement suitably deform | transforming within the range which does not change the summary. It is.

  For example, in the above-described embodiment, the TYPE-A module 30-1, the TYPE-B module 30-2, and the FeliCa (trademark) module 30-3 are configured to start in this order. -A module 30-1, TYPE-B module 30-2, and FeliCa (trademark) module 30-3 may be changed to other orders according to the frequency of use.

  In the above embodiment, the reception data received by the reception circuit 26 is directly added to the CPU 29, and the reception data from the CPU 29 is sent to the TYPE-A module 30-1, the TYPE-B module 30-2, and the FeliCa (trademark) module 30-. 3 is configured to transmit by serial communication, but as shown in FIG. 5, the drive driven by the CPU 29 by the chip select signal CS4 which is turned on when any of the chip select signal CS1, CS2 or CS3 is turned on A circuit 290 is provided, and the received data received by the receiving circuit 26 is transmitted via the drive circuit 290 to the TYPE-A module 30-1, the TYPE-B module 30-2, and the FeliCa ™ module 30-3 by serial communication. You may comprise.

DESCRIPTION OF SYMBOLS 1 Antenna 2 Receiver 3 Transmitter 4 Carrier separation circuit 5-1 Digital demodulator for TYPE-A 5-2 Digital demodulator for TYPE-B 5-3 Digital demodulator for FeliCa (trademark) 6 Received data extractor 10 RF Module (wireless circuit)
DESCRIPTION OF SYMBOLS 11 Induction power supply part 21 Crystal oscillator 22 A / D conversion circuit 23 Switch circuit 24 Pulse counter 25 Sampling timer 26 Reception circuit 27 Memory 28 Sampling count data table 29 CPU
30-1 TYPE-A module (card processing circuit)
30-2 TYPE-B module (card processing circuit)
30-3 FeliCa ™ module (card processing circuit)
290 Drive circuit

Claims (3)

A non-contact type IC card that is driven by electric power generated by electromagnetic induction of a carrier wave conveyed from a reader / writer, and communicates with the reader / writer by modulation of the carrier wave,
The frequency of the carrier used for the communication is the same, but a plurality of card processing circuits each having a different communication speed, modulation method, and encoding method,
A radio circuit capable of transmitting and receiving a carrier wave used by the plurality of card processing circuits;
A frequency detection means for detecting a frequency of a carrier wave from the reader / writer received by the radio circuit;
When the frequency detected by the frequency detection means matches the frequency of the carrier wave used by the plurality of card processing circuits, activation control means for sequentially starting the plurality of card processing circuits;
Discriminating means for discriminating whether an analysis error of received data occurs in an initial response operation in each card processing circuit by sequential activation by the activation control means;
A non-contact type IC card comprising: activation control means for selectively controlling the card processing circuit in which the analysis error of the received data does not occur in the discrimination means. The wireless circuit is
A plurality of modulation / demodulation circuits respectively corresponding to the plurality of card processing circuits;
2. The contactless IC according to claim 1, wherein modulation / demodulation of the carrier wave is performed using a modulation / demodulation circuit corresponding to the card processing circuit activated or activated by the activation control unit and the activation unit among the plurality of modulation / demodulation circuits. card. The frequency detection means includes
An analog-digital conversion circuit that analog-digital converts a carrier wave from the reader / writer received by the wireless circuit and outputs a pulse signal;
When the amplitude of the carrier wave is stable, a switch circuit that is turned on and passes a pulse signal output from the analog-digital conversion circuit;
A sampling timer that starts measuring a predetermined sampling time by turning on the switch circuit;
A pulse counter that counts the pulses of the pulse signal output from the analog-digital conversion circuit that has passed through the switch circuit during the time measured by the sampling timer, and
The non-contact type IC card according to claim 1, wherein the frequency of the carrier wave is detected based on count data of the pulse counter.

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