JP5628116B2 - Portable recording medium, portable recording medium control method, and portable recording medium control program - Google Patents

Description

  The present invention relates to a portable recording medium, a portable recording medium control method, and a portable recording medium control program.

  In recent years, with respect to portable recording media such as non-contact IC cards and portable terminals equipped with non-contact interfaces, with the progress of standardization for multiple communication methods (non-contact communication interfaces), multiple types of portable media that conform to standard specifications are available. Recording media have been developed. Conventionally, portable recording media are often developed in combination with a contactless card reader / writer having a corresponding contactless communication interface. For this reason, a portable recording medium having a non-contact communication interface cannot communicate with a non-contact card reader / writer having a different non-contact communication interface, and a plurality of non-contact communication being developed recently. In using a portable recording medium having an interface, it has been a problem to determine a non-contact communication interface corresponding to a non-contact card reader / writer.

  In contrast, in a portable recording medium having a plurality of specific contactless communication interfaces, a contactless communication interface corresponding to the contactless card reader / writer is determined based on a signal waveform transmitted from the contactless card reader / writer. Technology exists (for example, Patent Document 1).

Japanese Patent No. 4167120

  However, the prior art has only a specific kind of contactless communication interface (specifically, only two contactless communication interfaces of ISO / IEC14443 type A card and type B card). This is a method for determining a non-contact communication interface in a portable recording medium. Therefore, for example, JIS X 6319-4, which is widely used as a de facto standard in Japan, cannot be used to distinguish non-contact communication interfaces other than non-contact communication interfaces for type A and type B cards.

  Accordingly, an object of the present invention made in view of the above-described problems is to provide a non-contact communication interface for various non-contact card reader / writers including JIS X 6319-4 which is widely used as a de facto standard in Japan. Is to provide a portable recording medium, a portable recording medium control method, and a portable recording medium control program.

In order to solve the above problems, a portable recording medium according to the present invention provides:
A portable recording medium having a plurality of contactless communication interfaces,
An antenna circuit for detecting an unmodulated waveform and receiving a request signal subsequent to the unmodulated waveform;
A plurality of said amplitude value of said unmodulated wave antenna circuit detects an amplitude value indicating a feature point of the request signal transmitted after the start of the modulation waveform, the amplitude value set for each of the plurality of non-contact communication interface A memory for storing a threshold of
Based on the amplitude value of the non-modulated waveform stored in the memory, the amplitude value indicating the characteristic point of the modulated waveform after the start of transmission of the request signal, and the plurality of threshold values , the plurality of non-contact interfaces A signal processing unit for determining a non-contact interface;
I have a,
The memory stores amplitude values of a plurality of modulation waveforms acquired at a predetermined sampling rate after the request signal transmission start as an amplitude value indicating a characteristic point of the modulation waveform after the request signal transmission start,
The signal processing unit calculates a difference between amplitude values of adjacent modulation waveforms based on amplitude values of the plurality of modulation waveforms, and determines a type of a non-contact interface based on the difference. .

The control method of the portable recording medium according to the present invention includes:
A method for controlling a portable recording medium comprising a plurality of non-contact communication interfaces,
Detecting an unmodulated waveform and receiving a request signal following the unmodulated waveform;
The amplitude value of the detected said unmodulated wave, and the amplitude value that indicates the feature points of the request signal transmitted after the start of the modulation waveform, and a plurality of threshold values according to the amplitude value set for each of the plurality of non-contact communication interface A step of storing
Based on the amplitude value indicating the characteristic point of the stored non-modulated waveform, the amplitude value of the modulated waveform after the start of transmission of the request signal, and the plurality of threshold values , a predetermined non-contact from the plurality of non-contact interfaces Determining the interface;
Only including,
In the storing step, as the amplitude value of the modulation waveform indicating the feature point after the request signal transmission start, the amplitude value of a plurality of modulation waveforms acquired at a predetermined sampling rate after the request signal transmission start is stored,
A difference between amplitude values of adjacent modulation waveforms is calculated based on the amplitude values of the plurality of modulation waveforms, and the type of the non-contact interface is determined based on the difference.

A control program for a portable recording medium according to the present invention includes:
In a computer operating as a portable recording medium having a plurality of non-contact communication interfaces,
Detecting an unmodulated waveform and receiving a request signal following the unmodulated waveform;
The amplitude value of the detected said unmodulated wave, and the amplitude value that indicates the feature points of the request signal transmitted after the start of the modulation waveform, and a plurality of threshold values according to the amplitude value set for each of the plurality of non-contact communication interface And the procedure to store
Based on the stored amplitude value of the non-modulated waveform, the amplitude value indicating the characteristic point of the modulated waveform after transmission of the request signal, and the plurality of threshold values , a predetermined non-contact from the plurality of non-contact interfaces The procedure to determine the interface;
A control program of the portable recording medium for causing execution,
In the storing procedure, as the amplitude value indicating the characteristic point of the modulation waveform after the request signal transmission start, the amplitude value of a plurality of modulation waveforms acquired at a predetermined sampling rate after the request signal transmission start is stored,
A difference between amplitude values of adjacent modulation waveforms is calculated based on the amplitude values of the plurality of modulation waveforms, and the type of the non-contact interface is determined based on the difference.

  According to the portable recording medium, the portable recording medium control method, and the portable recording medium control program of the present invention, various non-standards including JIS X 6319-4, which are widely used as the de facto standard in Japan, are used. The contactless communication interface of the contact card reader / writer can be determined.

It is a lineblock diagram of portable recording medium 1 concerning one embodiment of the present invention. It is an example of threshold data stored in the memory 16. It is a figure which shows the example of the waveform figure of the received signal which the portable recording medium 1 receives from a non-contact card reader / writer. It is a flowchart which shows operation | movement of the portable recording medium 1 which concerns on one Embodiment of this invention. It is the conceptual diagram which illustrated the waveform of the signal by a predetermined non-contact communication interface, and the timing of the amplitude value which the portable recording medium 1 measured. It is an example of measurement data stored in the memory 16.

  Embodiments of the present invention will be described below.

(Embodiment)
FIG. 1 is a block diagram of a portable recording medium 1 according to an embodiment of the present invention. A portable recording medium 1 according to an embodiment of the present invention includes an antenna circuit 11, a clock reproduction unit 12, an amplification circuit 13, an AD conversion circuit 14, a signal processing unit 15, a memory 16, and a discrimination result output. Unit 17. Among these, the signal processing unit 15 and the memory 16 are provided in the logic circuit of the portable recording medium 1. The portable recording medium 1 is provided with a plurality of non-contact communication interfaces. In the following description, it is assumed that the portable recording medium 1 includes a first communication interface, a second communication interface, and a third communication interface. For example, the first communication interface is a contactless communication interface for an ISO / IEC14443 type A card, the second communication interface is a contactless communication interface for an ISO / IEC14443 type B card, and the third communication interface. Is a non-contact communication interface for JIS X 6319-4, but is not limited thereto.

  The antenna circuit 11 detects a non-modulated waveform transmitted from a non-contact card reader / writer through a predetermined non-contact communication interface, and receives a request signal.

  The clock reproduction unit 12 reproduces a clock used in the portable recording medium 1. Specifically, the clock reproduction unit 12 reproduces a clock used in the portable recording medium 1 based on an AC voltage of 13.56 MHz generated in the antenna circuit 11 by a signal transmitted from the contactless card reader / writer. . The portable recording medium 1 synchronizes with the contactless card reader / writer on the basis of the clock, and controls various processing timings in the portable recording medium 1.

  The amplifier circuit 13 amplifies the unmodulated waveform or the request signal detected by the antenna circuit 11. The AD conversion circuit 14 converts the unmodulated waveform or the request signal amplified by the amplification circuit 13 from an analog signal to a digital signal.

  The signal processing unit 15 measures a physical quantity of an unmodulated waveform or a request signal converted into a digital signal by the AD conversion circuit 14 and stores the measured physical quantity in the memory 16 as measurement data. The physical quantity is preferably an amplitude value. Hereinafter, the physical quantity is described as being an amplitude value, but is not limited thereto. The signal processing unit 15 observes the amplitude of the unmodulated waveform from moment to moment, and stores the amplitude value of the signal at the time when it is determined to be an unmodulated waveform in the memory 16 so that the received signal is unmodulated waveform or modulated. It is assumed that it is a waveform, and the method described in Patent Document 1 is used to determine the unmodulated waveform.

  Further, the signal processing unit 15 acquires the measurement data stored in the memory 16 and the first threshold value or the second threshold value for non-contact communication interface determination, performs a predetermined calculation based on the measurement data stored in the memory 16, It is determined whether or not the first threshold value or the second threshold value is exceeded. Based on this determination, the signal processing unit 15 determines the non-contact communication interface of the non-contact card reader / writer.

  Further, the signal processing unit 15 appropriately sets and increments i, which is a counter variable, and acquires a predetermined number of amplitude values of the unmodulated waveform or the request signal. Preferably, the amplitude value of the unmodulated waveform or request signal is numbered by the variable i for the counter, and the amplitude value of the i-th unmodulated waveform or request signal is stored in the memory 16 as the i-th measurement data. .

  The memory 16 includes measurement data of an unmodulated waveform or request signal amplitude value measured by the signal processing unit 15, first and second threshold values for non-contact communication interface determination, and counter variables. i is stored.

  The discrimination result output unit 17 outputs the discrimination result of the non-contact communication interface of the non-contact card reader / writer. The output result is preferably recorded on a medium such as an SD card or a flash memory (not shown). Based on the output result, the portable recording medium 1 autonomously switches to a contactless communication interface corresponding to the contactless card reader / writer and communicates with the contactless card reader / writer.

  FIG. 2 shows threshold data for non-contact communication interface discrimination stored in the memory 16. In FIG. 2, the first threshold value and the second threshold value are stored, and the threshold values are “1.75” and “0.05”, respectively. The threshold data is provided for each non-contact communication interface for determining the non-contact communication interface.

  FIG. 3 shows an example of a non-modulated waveform detected by the portable recording medium 1 and a waveform at the beginning of the request signal. The waveform of FIG. 3 is a waveform envelope drawn for convenience of description, but is actually filled with a carrier having a carrier frequency of 13.56 MHz. FIG. 3 shows three types of non-contact communication interfaces for unmodulated waveforms and request signals, respectively, in FIGS. 3 (a) to 3 (c). The portable recording medium 1 according to an embodiment of the present invention is based on a physical quantity indicating the characteristic points of the unmodulated waveform and the waveform of the head portion of the request signal shown in FIGS. 3 (a) to 3 (c). Determine the non-contact communication interface.

  FIG. 3A is an example of a waveform generated by the first communication interface. For example, a waveform of a contactless communication interface for a type A card defined by ISO / IEC14443 is represented by the waveform. In FIG. 3A, the horizontal axis represents time, and the vertical axis represents signal amplitude (signal voltage value).

As shown in FIG. 3A, the waveform first includes an unmodulated waveform for a certain period of time. The amplitude of the unmodulated waveform is a constant value (Hi). Following the unmodulated waveform is a request signal. The request signal is a signal for the non-contact card reader / writer to detect the presence of the portable recording medium 1. The top portion of the request signal shown in FIG. 3A includes a start bit, a bit “0”, a bit “1”, a bit “1”, and a bit “0”. The start bit is composed of 32 low amplitude values (Lo) followed by 96 high amplitude values (Hi). More specifically, the value of the low amplitude value in FIG. 3A is 0, that is, the period is a pause period. One unit represents one unit of time, and preferably 0.0737 μsec (1 / 13.56 MHz). The start bit consists of 128 time unit signals, for a total of about 9 . The signal is 4 μs. Similarly, the bit “0” and the bit “1” are about 9 . The signal is 4 μs.

  Following the start bit, there is a bit “0” at the beginning of the request signal shown in FIG. Bit “0” is composed of 32 low amplitude values (Lo) followed by 96 high amplitude values (Hi) in the same manner as the start bit.

  Following the bit “0”, there are two bits “1” at the beginning of the request signal shown in FIG. The first two bits “1” are composed of 64 high amplitude values (Hi), followed by 32 low amplitude values (Lo), followed by 32 high amplitude values (Hi). Following the two bits “1”, there is a bit “0”. The bit “0” is composed of 128 high amplitude values (Hi), unlike the bit “0” after the start bit.

  FIG. 3B is an example of a waveform generated by the second communication interface. For example, a waveform of a contactless communication interface for a type B card defined by ISO / IEC14443 is represented by the waveform. Similar to FIG. 3A, the horizontal axis of FIG. 3B is time, and the vertical axis indicates the amplitude of the signal (voltage value of the signal).

  As shown in FIG. 3B, the waveform has an unmodulated waveform for a certain period of time. The amplitude of the unmodulated waveform is a constant value (Hi). Following the unmodulated waveform is a request signal. The head portion of the request signal shown in FIG. 3B is composed of an SOF signal. The SOF signal is composed only of a low amplitude value (Lo). Specifically, the value of the low amplitude value in FIG. 3B is 3.15 [V] when the amplitude of the unmodulated waveform is 3.5 [V], for example. This value is about 90% of the amplitude of the unmodulated waveform.

  FIG. 3C shows an example of a waveform generated by the third communication interface. For example, a waveform by a non-contact communication interface for JIS X 6319-4 is represented by the waveform. Similar to FIG. 3A, the horizontal axis of FIG. 3C represents time, and the vertical axis represents signal amplitude (signal voltage value).

  As shown in FIG. 3C, the waveform has an unmodulated waveform for a certain period of time. The amplitude of the unmodulated waveform is a constant value (Hi). Following the unmodulated waveform is a request signal. The top part of the request signal shown in FIG. 3C includes 10 bits “0”.

Bit “0” in FIG. 3C is composed of 32 low amplitude values (Lo) followed by 32 high amplitude values (Hi). One bit in FIG. 3C is composed of 64 time unit signals, and about 4 . The signal is 7 μs. Specifically, the value of the low amplitude value in FIG. 3C is, for example, 3.15 [V] when the amplitude of the unmodulated waveform is 3.5 [V]. This value is about 90% of the amplitude of the unmodulated waveform.

  Next, the operation of the portable recording medium 1 according to one embodiment of the present invention will be described with reference to the flowchart shown in FIG.

  First, the signal processing unit 15 measures the amplitude value of the non-modulated waveform transmitted from the non-contact card reader / writer. Then, the signal processing unit 15 stores the measured amplitude value in the memory 16 (step S1). Specifically, the antenna circuit 11 detects an unmodulated waveform transmitted from the contactless card reader / writer, the amplification circuit 13 subsequently amplifies the waveform, and the AD conversion circuit 14 converts the signal from analog data. Convert to digital data. Then, the signal processing unit 15 measures the amplitude value of the unmodulated waveform based on the digital data, and stores it in the memory 16 as measurement data. The signal processing unit 15 stores a value obtained by multiplying the measured data of the unmodulated waveform by 0.5 in the memory 16 as the first threshold value. Of the threshold data shown in FIG. 2, the first threshold is data stored in this way. FIG. 2 shows an example in which the amplitude value of the unmodulated waveform is 3.50 [V]. ing. Note that the amplitude value of the unmodulated waveform may take a different value depending on system conditions such as a power supply voltage in the portable recording medium 1.

Next, the signal processing unit 15 measures the amplitude value of the signal of the modulation waveform immediately after the start of signal transmission of the request signal following the unmodulated waveform, and stores the measured amplitude value in the memory 16 (step S2). Here, immediately after the start of signal transmission of the request signal is about 2 . It means a period of less than 35 μs. The amplitude value is a physical quantity indicating the first feature point for discrimination of the non-contact communication interface. Specifically, the antenna circuit 11 receives a signal transmitted from the contactless card reader / writer, the amplification circuit 13 subsequently amplifies the signal, and the AD conversion circuit 14 converts the signal from an analog signal to a digital signal. Convert to The signal processing unit 15 measures the amplitude value of the modulation waveform signal based on the digital signal.

  Subsequently, the signal processing unit 15 acquires from the memory 16 the amplitude value of the modulation waveform stored in step S2 and the first threshold stored in step S1. Then, the signal processing unit 15 determines whether or not the amplitude value of the modulation waveform is greater than or equal to the first threshold (step S3). If it is less than the first threshold, the process proceeds to step S4, and if it is greater than or equal to the first threshold, the process proceeds to step S5.

  If the amplitude value of the modulation waveform is less than the first threshold value in step S3, the discrimination result output unit 17 discriminates that the non-contact communication interface of the non-contact card reader / writer is the first interface, and determines the discrimination result. Output (step S4), the process ends. The determination result is preferably recorded on a medium such as an SD card or a flash memory (not shown). Based on the determination result, the portable recording medium 1 autonomously switches to the first communication interface corresponding to the contactless card reader / writer and communicates with the contactless card reader / writer.

If the amplitude value of the modulation waveform is greater than or equal to the first threshold value in step S3, the signal processing unit 15 measures the amplitude value of the request signal that is the subsequent modulation waveform (N + 1) times, and stores the measured amplitude value in the memory. 16. In the following description, it is assumed that N is 10. However, the present invention is not limited to this, and N may be more or less than 10. The signal processing unit 15 controls an interval for measuring a plurality of times (hereinafter referred to as a sampling interval) based on the clock regenerated by the clock regenerating unit 12. The sampling interval is preferably 2 . 35 μs. The sampling interval is determined based on the interval of the non-contact communication interface having the shortest interval at which Hi and Lo time fluctuations occur in each non-contact communication interface. According to the signal waveforms of the non-contact communication interfaces shown in FIGS. 3A to 3C, the interval at which the time fluctuations of Hi and Lo occur is the shortest in FIG . Since it is 35 μs, the sampling interval can be most efficiently processed by setting it based on the time interval. The plurality of amplitude values are physical quantities indicating feature points for discrimination of the non-contact communication interface.

  In order to measure the amplitude value of the request signal a plurality of times, first, the signal processing unit 15 sets the counter variable i to 2 (step S5). Subsequently, the signal processing unit 15 measures the amplitude value of the i-th, that is, the second request signal, and stores the measured amplitude value in the memory 16 (step S6). Specifically, the antenna circuit 11 receives a signal transmitted from the contactless card reader / writer, the amplification circuit 13 subsequently amplifies the signal, and the AD conversion circuit 14 converts the signal from an analog signal to a digital signal. Convert to The signal processing unit 15 measures the amplitude value of the request signal based on the digital signal.

  Subsequently, the signal processing unit 15 determines whether or not the variable i is N + 1, that is, 11 or more (step S7). Since i is 2 at this time, the process proceeds to step S8.

  Subsequently, the signal processing unit 15 increments the value of the variable i, that is, adds 1 to the value of i (step S8). Since i is 2, i is 3 as a result of the increment.

  Thus, by repeating step S6 to step S8 until the value of i becomes N + 1, that is, 11, the signal processing unit 15 measures the amplitude value of the second to eleventh request signals, and the measured amplitude value is obtained. Stored in the memory 16 as measurement data.

  When the signal processing unit 15 determines in step S7 that the value of i is N + 1 or more (that is, 11 or more), the signal processing unit 15 calculates a difference between temporally adjacent amplitude values among the amplitude values of the request signal. Is calculated (step S9). Then, the signal processing unit 15 stores the absolute value of the difference between the calculated temporally adjacent amplitude values in the memory 16.

  Subsequently, the signal processing unit 15 calculates the value X of the left side in the following Equation 1, and determines whether or not the value X is equal to or greater than the second threshold (step S10).

In the present case, N on the right side is 10 as described above. The “measurement data _n ” on the right side represents the nth measurement data.

  That is, the signal processing unit 15 calculates the sum of the absolute values of the differences from the absolute value of the difference between the amplitude values adjacent in time, using Equation 1, and a value obtained by multiplying the sum by N times the amplitude value of the unmodulated waveform. The value X divided by is calculated. Then, the signal processing unit 15 determines whether or not the value X is greater than or equal to the second threshold value.

  If the value X is less than the second threshold value as a result of the determination in step S10, the determination result output unit 17 determines that the non-contact communication interface of the non-contact card reader / writer is the second interface. The result is output (step S11), and the process ends. The determination result is preferably recorded on a medium such as an SD card or a flash memory (not shown). Based on the determination result, the portable recording medium 1 autonomously switches to the second communication interface corresponding to the contactless card reader / writer and communicates with the contactless card reader / writer. The portable recording medium 1 communicates with the non-contact card reader / writer based on the output result.

  If the value X is less than the second threshold as a result of the determination in step S10, the determination result output unit 17 determines that the non-contact communication interface of the non-contact card reader / writer is the third interface. The result is output (step S12), and the process ends. The determination result is preferably recorded on a medium such as an SD card or a flash memory (not shown). Based on the determination result, the portable recording medium 1 autonomously switches to the third communication interface corresponding to the contactless card reader / writer and communicates with the contactless card reader / writer. The portable recording medium 1 communicates with the non-contact card reader / writer based on the output result.

  Hereinafter, the operation in the case of receiving a signal in each non-contact communication interface specifically shown in FIGS. 3A to 3C will be described in detail with reference to FIGS.

(Operation example when a signal is received by the first communication interface)
FIG. 5A is a conceptual diagram illustrating the waveform transmitted by the first communication interface and the timing of the amplitude value measured by the portable recording medium 1 by the above operation. The waveform in FIG. 5A is a waveform envelope drawn for convenience of description, but is actually filled with a carrier having a carrier frequency of 13.56 MHz. The conceptual diagram shown in FIG. 5A illustrates that the signal processing unit 15 acquires _first measurement data (hereinafter referred to as measurement data ₁ ).

When the portable recording medium 1 receives the signal shown in FIG. 5A, the signal processing unit 15 stores the measurement data shown in FIG. Specifically, when the portable recording medium 1 receives the signal shown in FIG. 5A, the signal processing unit 15 stores the amplitude value of the unmodulated waveform in step S1. Further, the signal processing unit 15 stores the amplitude value of the modulation waveform in step S2. The unmodulated waveform measurement data and the modulation waveform measurement data ₁ stored in the memory 16 by the signal processing unit 15 are 3.50 [V] and 0.00 [V], respectively.

  Subsequently, in step S3, the signal processing unit 15 determines that the amplitude value of the modulation waveform is 0.00, so that it is less than the first threshold, that is, less than 1.75.

  In step S4, the discrimination result output unit 17 outputs a result of discriminating that the non-contact communication interface of the non-contact card reader / writer is the first interface.

  In the above example, the signal processing unit 15 does not measure the measurement data of the subsequent modulation waveform, and does not store the measurement data in the memory 16. In FIG. 6A, the fact that the data is not stored in the memory 16 is indicated by hatching.

(Operation example when receiving a signal through the second communication interface)
FIG. 5B is a conceptual diagram illustrating the timing of the waveform transmitted by the second communication interface shown in FIG. 3B and the amplitude value measured by the portable recording medium 1 by the above operation. The waveform of FIG. 5B is a waveform envelope drawn for convenience of description, but is actually filled with a carrier having a carrier frequency of 13.56 MHz. The conceptual diagram shown in FIG. 5B illustrates that the signal processing unit 15 acquires _eleventh measurement data (hereinafter referred to as measurement data ₁ to measurement data ₁₁ ) from the _first measurement data. ing.

When the portable recording medium 1 receives the signal shown in FIG. 5B, the signal processing unit 15 stores the measurement data shown in FIG. 6B in the memory 16 based on the above operation. Specifically, when the portable recording medium 1 receives the signal shown in FIG. 5B, the signal processing unit 15 stores the amplitude value of the unmodulated waveform in step S1. Further, the signal processing unit 15 stores the amplitude value of the modulation waveform in step S2. The unmodulated waveform measurement data and the modulation waveform measurement data ₁ stored in the memory 16 by the signal processing unit 15 are 3.50 [V] and 3.15 [V], respectively.

  Subsequently, the signal processing unit 15 determines in step S3 that the amplitude value of the modulation waveform is 3.15, which is greater than or equal to the first threshold value. In step S5, the signal processing unit 15 measures the measurement data of the request signal that is the subsequent modulation waveform.

In subsequent steps S <b> 5 to S <b> 7, the signal processing unit 15 measures amplitude values of a plurality of subsequent request signals and sequentially stores them in the memory 16. The measurement data ₂ to measurement data ₁₁ of the request signal stored in the memory 16 by the signal processing unit 15 are 3.15 [V], 3.15 [V], 3.15 [V], and 3.08 [V], respectively. 3.08 [V], 3.08 [V], 3.15 [V], 3.15 [V], 3.22 [V], 3.22 [V].

  Subsequently, in step S <b> 9, the signal processing unit 15 calculates the absolute value of the difference between the amplitude values adjacent in time among the amplitude values of the request signal, and stores the value in the memory 16. The absolute values of the differences stored in the memory 16 by the signal processing unit 15 are 0.00, 0.00, 0.00, 0.07, 0.00, 0.00, 0.07, 0.00, and 0, respectively. .07, 0.00.

  Subsequently, in step S10, the signal processing unit 15 calculates a value X based on Equation 1. Specifically, the signal processing unit 15 calculates 0.21 that is the sum of the absolute values of the differences from the absolute value of the difference between the adjacent amplitude values in terms of time. Then, the signal processing unit 15 calculates the value X by dividing the sum by N times (10 times, 35 in this case) the amplitude value of the unmodulated waveform. Then, the signal processing unit 15 determines that the value X is 0.006 and is less than the second threshold value.

  In step S11, the determination result output unit 17 outputs a result of determining that the non-contact communication interface of the non-contact card reader / writer is the second interface.

(Operation example when a signal is received by the third communication interface)
FIG. 5C is a conceptual diagram illustrating the waveform of the signal transmitted by the third communication interface shown in FIG. 3C and the timing of the amplitude value measured by the portable recording medium 1 by the above operation. is there. The waveform shown in FIG. 5C is a waveform envelope drawn for convenience of description, but is actually filled with a carrier having a carrier frequency of 13.56 MHz. The conceptual diagram shown in FIG. 5C shows that the signal processing unit 15 acquires measurement data ₁ to measurement data ₁₁ .

When the portable recording medium 1 receives the signal shown in FIG. 5C, the signal processing unit 15 stores the measurement data shown in FIG. 6C in the memory 16 based on the above operation. Specifically, when the portable recording medium 1 receives the signal shown in FIG. 5C, the signal processing unit 15 stores the amplitude value of the unmodulated waveform in step S1. Further, the signal processing unit 15 stores the amplitude value of the modulation waveform in step S2. The unmodulated waveform measurement data and the modulation waveform measurement data ₁ stored in the memory 16 by the signal processing unit 15 are 3.50 [V] and 3.15 [V], respectively.

  Subsequently, the signal processing unit 15 determines in step S3 that the amplitude value of the modulation waveform is 3.15, which is greater than or equal to the first threshold value. In step S5, the signal processing unit 15 measures the measurement data of the subsequent modulation waveform.

In subsequent steps S <b> 5 to S <b> 7, the signal processing unit 15 measures amplitude values of a plurality of subsequent modulation waveforms and sequentially stores them in the memory 16. The modulation waveform measurement data ₂ to measurement data ₁₁ stored in the memory 16 by the signal processing unit 15 are 3.50 [V], 3.15 [V], 3.50 [V], and 3.15 [V], respectively. 3.50 [V], 3.15 [V], 3.43 [V], 3.15 [V], 3.50 [V], and 3.15 [V].

  Subsequently, in step S <b> 9, the signal processing unit 15 calculates the absolute value of the difference between the amplitude values adjacent in time among the amplitude values of the modulation waveform, and stores the value in the memory 16. The absolute values of the differences stored in the memory 16 by the signal processing unit 15 are 0.35, 0.35, 0.35, 0.35, 0.35, 0.35, 0.28, 0.28, 0, respectively. .35, 0.35.

  Subsequently, the signal processing unit 15 calculates the value X based on Equation 1 in step S10. Specifically, the signal processing unit 15 calculates 3.36, which is the sum of the absolute values of the differences, from the absolute values of the differences between the adjacent amplitude values in terms of time. The signal processing unit 15 calculates the value X by dividing the sum by N times (10 times, 35 in this case) the amplitude value of the unmodulated waveform. Then, the signal processing unit 15 determines that the value X is 0.096 and is equal to or greater than the second threshold value.

  In step S12, the determination result output unit 17 outputs a result of determining that the non-contact communication interface of the non-contact card reader / writer is the third interface.

  Thus, according to the present invention, the signal processing unit 15 uses the first communication interface based on the amplitude of the unmodulated waveform stored in the memory 16, the first threshold value, and the amplitude value of the modulated signal immediately after sending the request signal. And the amplitude of the unmodulated waveform stored in the memory 16, the second threshold value, and the amplitude values of a plurality of request signals acquired at a predetermined sampling rate after the start of sending the request signal. Since the second communication interface and the third communication interface can be discriminated based on the above, non-contact communication of various non-contact card reader / writers including JIS X 6319-4 which is widely used as a de facto standard in Japan The interface can be determined.

In particular, in the case of a received signal related to the first communication interface shown in FIG. 3A where the difference between the high amplitude value (Hi) and the low amplitude value (Lo) is large, the signal processing unit 15 starts counting from the request signal transmission time point. In order to determine a non-contact communication interface at the time of measurement of the first amplitude value, 2 . High-speed judgment can be made in a short time of 35 μs.

  Further, according to the present invention, the signal processing unit 15 measures the amplitude values of the plurality of modulation waveforms at Steps S5 to S8, and the contactless communication interface of the contactless card reader / writer based on the amplitude values of the plurality of modulation waveforms. Therefore, it is difficult to distinguish between a high amplitude value (Hi) and a low amplitude value (Lo) as in ASK 10% (especially when the portable recording medium 1 or the non-contact card reader / writer is used by moving it). Even if the signal amplitude changes from moment to moment, it becomes a significant problem), and the contactless communication interface can be discriminated more accurately and stably.

  Although the absolute value of the difference is calculated in Formula 1, the present invention is not limited to this, and the sum of the squares of the differences may be used. In this case, the second threshold value is adjusted as appropriate.

  Here, in order to function as the portable recording medium 1, a computer can be preferably used, and such a computer can store a program describing processing contents for realizing each function of the portable recording medium 1. This program can be realized by reading out and executing this program by a central processing unit (CPU) of the computer.

  Although the present invention has been described based on the drawings and examples, it should be noted that those skilled in the art can easily make various modifications and corrections based on the present disclosure. Therefore, it should be noted that these variations and modifications are included in the scope of the present invention. For example, the functions included in each means, each step, etc. can be rearranged so that there is no logical contradiction, and a plurality of means, steps, etc. can be combined or divided into one. .

DESCRIPTION OF SYMBOLS 1 Portable recording medium 11 Antenna circuit 12 Clock reproduction | regeneration part 13 Amplification circuit 14 AD conversion circuit 15 Signal processing part 16 Memory 17 Discrimination result output part

Claims (4)

A portable recording medium having a plurality of contactless communication interfaces,
An antenna circuit for detecting an unmodulated waveform and receiving a request signal subsequent to the unmodulated waveform;
A plurality of said amplitude value of said unmodulated wave antenna circuit detects an amplitude value indicating a feature point of the request signal transmitted after the start of the modulation waveform, the amplitude value set for each of the plurality of non-contact communication interface A memory for storing a threshold of
Based on the amplitude value of the non-modulated waveform stored in the memory, the amplitude value indicating the characteristic point of the modulated waveform after the start of transmission of the request signal, and the plurality of threshold values , the plurality of non-contact interfaces A signal processing unit for determining a non-contact interface;
I have a,
The memory stores amplitude values of a plurality of modulation waveforms acquired at a predetermined sampling rate after the request signal transmission start as an amplitude value indicating a characteristic point of the modulation waveform after the request signal transmission start,
The signal processing unit calculates a difference between amplitude values of adjacent modulation waveforms based on amplitude values of the plurality of modulation waveforms, and determines a type of a non-contact interface based on the difference. <br/> Portable recording media. 2. The portable recording medium according to claim 1, wherein the amplitude value indicating the characteristic point of the modulation waveform after the request signal transmission is started is the amplitude value of the modulation waveform immediately after the request signal transmission is started. A method for controlling a portable recording medium comprising a plurality of non-contact communication interfaces,
Detecting an unmodulated waveform and receiving a request signal following the unmodulated waveform;
The amplitude value of the detected said unmodulated wave, and the amplitude value that indicates the feature points of the request signal transmitted after the start of the modulation waveform, and a plurality of threshold values according to the amplitude value set for each of the plurality of non-contact communication interface A step of storing
Based on the amplitude value indicating the characteristic point of the stored non-modulated waveform, the amplitude value of the modulated waveform after the start of transmission of the request signal, and the plurality of threshold values , a predetermined non-contact from the plurality of non-contact interfaces Determining the interface;
Only including,
In the storing step, as the amplitude value of the modulation waveform indicating the feature point after the request signal transmission start, the amplitude value of a plurality of modulation waveforms acquired at a predetermined sampling rate after the request signal transmission start is stored,
The difference between the amplitude values of adjacent modulation waveforms is calculated based on the amplitude values of the plurality of modulation waveforms, and the type of the non-contact interface is determined based on the difference. Recording medium control method. In a computer operating as a portable recording medium having a plurality of non-contact communication interfaces,
Detecting an unmodulated waveform and receiving a request signal following the unmodulated waveform;
The amplitude value of the detected said unmodulated wave, and the amplitude value that indicates the feature points of the request signal transmitted after the start of the modulation waveform, and a plurality of threshold values according to the amplitude value set for each of the plurality of non-contact communication interface And the procedure to store
Based on the stored amplitude value of the non-modulated waveform, the amplitude value indicating the characteristic point of the modulated waveform after transmission of the request signal, and the plurality of threshold values , a predetermined non-contact from the plurality of non-contact interfaces The procedure to determine the interface;
A control program of the portable recording medium for causing execution,
In the storing procedure, as the amplitude value indicating the characteristic point of the modulation waveform after the request signal transmission start, the amplitude value of a plurality of modulation waveforms acquired at a predetermined sampling rate after the request signal transmission start is stored,
A program that calculates a difference between amplitude values of adjacent modulation waveforms based on amplitude values of the plurality of modulation waveforms, and determines a type of a non-contact interface based on the differences.

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