JPH09161029A - Data access device for non-contact ic card - Google Patents

Abstract

PROBLEM TO BE SOLVED: To precisely read out transmission data from a non-contact IC card by mutually adding positive and negative rectified signals and outputting the added result as a threshold signal. SOLUTION: An inputted carrier (a) is turned to positive and negative rectified signals (b) through a rectifying means consisting of a preamplifier 51, an operational amplifier 53, diodes 57, 59, and resistors 52, 54, 58, 60. Then, the positive rectified signal is averaged through a threshold signal generating means consisting of a resistor 61 and a capacitor 62 and the negative rectified signal is averaged through a threshold signal generating means consisting of a resistor 64 and a capacitor 65. The positive and negative rectified signals are mutually added through a threshold signal generating means consisting of resistors 63, 66. A comparator 56 to be a comparing means compares an wave (e) to be a threshod with the carrier (a) and outputs a waveform corresponding to a compared result. Thereby, the comparator 56 outputs an accurate digital signal to a demodulation circuit.

Description

Detailed Description of the Invention

[0001]

TECHNICAL FIELD The present invention relates to a non-contact IC (I
The present invention relates to a non-contact IC card data access device used in a reader / writer device of an integrated circuit card communication system and capable of expanding a communication range.

[0002]

2. Description of the Related Art FIG. 12 is a block diagram showing the structure of a conventional non-contact IC card data access device.
Reference numeral 1 is a non-contact IC card, 2 is a one-chip IC of the non-contact IC card 1, ROM for storing programs, data, etc., RAM for temporarily storing data and being used as a working area, crystal oscillator circuit 3 has a CPU that executes a program based on a clock supplied from the CPU 3, a modulator / demodulator, and the like. Reference numeral 4 is a loop antenna for radiating and receiving radio waves, 5 is a power supply control unit for generating electric power from the radio waves received by the loop antenna 4, and supplying power to the 1-chip IC 2 and the like, and 6 is a power supply capacitor.

A read / write device 11 writes / reads data to / from the non-contact IC card 1 and has a transmission function and a reception function. As the transmission function, programs, data, etc. are stored. ROM, RAM that temporarily stores data and is used as a working area, CPU that executes programs based on the clock supplied from the crystal oscillator circuit, and 12 is data that can be exchanged with other devices via a cable. A microcomputer board having a serial communication unit for communication, 13
Is a loop antenna for radiating and receiving radio waves, 14 is a coupling circuit of the read / write device 11, and 15 is a communication buffer.

Reference numeral 16 denotes a modulator for modulating the signal output from the communication buffer 15 for temporarily storing communication data by BPSK (Binary Phase Shift Keying), and 17 denotes the modulated communication data. It is an output amplifier that amplifies and outputs to the coupling circuit 14. Reference numeral 18 is a reception amplifier for amplifying the reception signal output from the coupling circuit 14, 19 is a limit, and 20 is demodulation of the reception signal after the limit 19 is converted into a rectangular waveform of a predetermined level and output to the communication buffer 15. The demodulation circuit 21 is a power supply unit.

Next, the operation will be described. The non-contact IC card 1 executes a program based on the clock supplied from the crystal oscillation circuit 3 and radiates and receives radio wave data via the loop antenna 4, but the power for driving the one-chip IC 2 is controlled by the power supply. The unit 5 generates electric power based on the radio wave (power signal) received by the loop antenna 4. on the other hand,
A read / write device 11 that writes and reads data to and from the non-contact IC card 1 has a transmission function and a reception function. The transmission function executes a program based on a clock supplied from a crystal oscillation circuit to a CPU. The communication buffer 15 which is executed and the modulator 16 temporarily stores communication data.
The signal output from the signal is modulated by BPSK (Binary Phase Shift Keying), and the output amplifier 17 amplifies the modulated communication data and outputs the amplified communication data to the coupling circuit 14, and the radio wave is output from the loop antenna 13. Radiate. In addition, the reception function of the reception amplifier 18 is the coupling circuit 14
After amplifying the received signal output from the limiter 19, the limit 19 converts it into a rectangular waveform of a predetermined level, and the demodulation circuit 20 demodulates the received signal and outputs it to the communication buffer 15. The power supply unit 21 converts alternating current from the commercial power supply line into direct current of a predetermined voltage and supplies it to each unit of the read / write device 11.

FIG. 13 is a system diagram showing the function of the data access device for the non-contact IC card shown in FIG. 12, and as shown in the figure, the transmission function of the read / write device 11 is the control data transmission function F1 and the power transmission. The function is F2, and the receiving function is only a card data receiving function F3 that receives data from the non-contact IC card 1. On the other hand, in the non-contact IC card 1, the control data transmitting function F1 corresponds to the control data receiving function F4, the control data transmitting function F1 and the power transmitting function F2 correspond to the AC / DC converting function F5, and the transmission wave is transmitted. Is converted into direct current and this electric power is supplied to each circuit of the non-contact IC card 1. Further, during power supply or during a power supply maintenance period, the control data F6 controls the data writing / reading operation according to the control data, and the data from the non-contact IC card 1 is transmitted by the card data transmission function F7 during the read control. To be done.

FIG. 14 is a circuit diagram specifically showing the coupling circuit 14 described with reference to FIG. As shown in the figure, the transmission data and the sine wave for power supply are supplied from the modulator 16 to the transmission winding 31 of the coupling transformer T. This signal is supplied to the antenna winding 32 by electromagnetic induction and transmitted from the loop antenna 13 to the non-contact IC card 1 in the vicinity as an electromagnetic wave. On the other hand, transmission data as a carrier wave from the non-contact IC card 1 is supplied to the antenna winding 32 via the loop antenna 13. This signal is a coupling transformer T
Of the comparator 3 via the transmission winding 33 and the resistor 34 of
5 is input to the minus input terminal. Further, the resistor 3 is provided between the output terminal and the negative input terminal of the comparator 35.
7 is connected. On the other hand, the positive input terminal of the comparator 35 is connected to the sliding terminal of the variable resistor 36.

FIG. 15 is a waveform diagram showing the threshold level when an incorrect waveform is input to the coupling circuit of FIG. In the figure, S is a threshold level, and when the voltage of the transmission data as a carrier is located in the positive direction from the threshold S fixedly set by the variable resistor 36, the output of the comparator 35 is a plus waveform. When the position is in the negative direction from the threshold S, the output of the comparator 35 has a negative waveform. However, when the noise of the negative DC component comes in, the entire waveform of the transmission data is shifted to the negative side as shown in FIG.

In this case, the threshold S
The threshold S
Since it is in the more negative direction, the output of the comparator 35 does not have a pulse waveform, and the read / write device 11 is a non-contact IC.
The transmission data from the card 1 could not be read accurately.

Further, since the self-test means for judging whether or not the transmission data from the non-contact IC card 1 can be accurately received is not provided, the reliability of reading the transmission data cannot be confirmed. .

[0011]

Since the conventional data access device for the non-contact IC card is constructed as described above, when the DC component noise is superimposed on the data transmitted from the non-contact IC card, it is received. Although the entire waveform of the data moves to the positive side or the negative side, if the entire waveform of the received data deviates from the threshold S, there is a problem that the comparator 35 cannot generate the pulse waveform.

Further, when the distance between the non-contact IC card 1 and the read / write device 11 becomes large and the output radio wave of the non-contact IC card 1 becomes very small, the read / write device 11
No means for increasing the voltage level of the power supply signal output from the power transmission function F2 of
There is also a problem that the read / write device 11 cannot communicate with the non-contact IC card 1 because it cannot follow the minute output radio wave.

Further, since the read / write device 11 does not have a self-test means for judging whether or not the transmission data from the non-contact IC card 1 can be correctly received, the reliability is inferior. There was also.

The present invention has been made to solve the above problems, and even when noise of positive or negative DC component is introduced and the entire waveform of transmission data moves from 0V in either direction. An object of the present invention is to obtain a non-contact IC card data access device capable of accurately reading transmission data from the non-contact IC card 1.

Further, according to the present invention, when the output radio wave of the non-contact IC card 1 becomes very small, the voltage level of the power supply signal is raised to read / write the device 1.
It is an object of the present invention to provide a non-contact IC card data access device capable of expanding the communication range between the non-contact IC card 1 and the non-contact IC card 1.

Further, the present invention is a non-contact IC card 1
It is an object of the present invention to provide a data access device for a non-contact IC card, which is provided with a self-test means for judging whether or not the transmission data from the device has been correctly received, and which can improve reliability.

[0017]

According to a first aspect of the present invention, there is provided a data access device for a non-contact type IC card, which shifts to a drive state when a power signal is received by a transmitting means, and stores it in a memory when a read signal is received. The power signal and the read signal are transmitted to the non-contact IC card that transmits the stored data, while the positive rectified signal and the negative rectified signal output from the rectifying means by the threshold signal generating means are added to each other, and The addition result is output as a threshold signal.

According to another aspect of the data access device of the non-contact type IC card of the present invention, when the power signal is received by the transmission means, the data access device transits to the driving state, and when the read / write signal is received, the data stored in the memory is transferred. While transmitting, a power signal and a read / write signal are transmitted to the non-contact IC card that stores data in the memory, while the positive rectified signal and the negative rectified signal output from the rectifying means by the threshold signal generating means are transmitted. The signals are added to each other and the addition result is output as a threshold signal.

A data access device for a contactless IC card according to a third aspect of the present invention smoothes positive and negative rectified signals and adds the smoothed positive rectified signal and negative rectified signal to each other. It is the one.

In the data access device for the non-contact IC card according to the present invention, the amplitude of the data received by the receiving means is increased when the absolute value of the negative rectified signal is smaller than the predetermined value. It is a thing.

According to the fifth aspect of the present invention, in the data access device for the non-contact type IC card, when the power signal is received by the transmitting means, the device transits to the driving state, and when the read signal is received, the data stored in the memory is transmitted. While transmitting the power signal and the read signal to the non-contact IC card, the pulse width on the positive side and the pulse width on the negative side of the pulse signal output from the comparing means are compared, and the pulse width on the positive side is negative. The threshold signal is increased to the positive side when it is larger than the pulse width on the side, and the threshold signal is increased to the negative side when the pulse width on the positive side is smaller than the pulse width on the negative side.

According to a sixth aspect of the present invention, there is provided a data access device for a contactless IC card, which transitions to a driving state when a power signal is received by the transmitting means, and stores the data stored in the memory when a read / write signal is received. A power signal and a read / write signal are transmitted to a non-contact IC card that transmits and stores data in its memory, while the positive pulse width and the negative pulse of the pulse signal output from the comparison means are transmitted. When the positive side pulse width is larger than the negative side pulse width, the threshold signal is increased to the positive side, and when the positive side pulse width is smaller than the negative side pulse width, the above threshold signal is negative. It is designed to be enlarged toward the side.

In the data access device for a non-contact IC card according to the seventh aspect of the present invention, when the rectifying means and the threshold signal generating means are tested, the frequency is ⅔ times the frequency of the read signal or the read / write signal. And the negative rectified signal are multiplied, and from the multiplication result, the read signal,
Alternatively, a signal having a frequency half the read / write signal is extracted, and the extracted signal is used as the data received by the receiving means.

The transmitting means of the non-contact IC card data access device according to the present invention determines the level of the power signal based on the reception level of the data received by the receiving means. .

[0025]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS One embodiment of the present invention will be described below. Embodiment 1 FIG. 1 is a configuration diagram showing a non-contact IC card data access device according to a first embodiment of the present invention, and FIG. 2 is a configuration diagram showing a part of a non-contact IC card data access device according to a first embodiment of the present invention. FIG. 7 is a waveform diagram showing the waveform of each part of the data access device of the non-contact IC card of FIG. In the figure, 1 is a non-contact IC card, 2 is a 1-chip IC of the non-contact IC card 1, ROM for storing programs, data, etc., R for temporarily storing data and used as a working area, etc.
It has an AM, a CPU that executes a program based on a clock supplied from the crystal oscillation circuit 3, a modulator / demodulator, and the like. Reference numeral 4 is a loop antenna for radiating and receiving radio waves, 5 is a power supply control unit for generating electric power from the radio waves received by the loop antenna 4, and supplying power to the 1-chip IC 2 and the like, and 6 is a power supply capacitor.

A read / write device 11 writes / reads data to / from the non-contact IC card 1 and has a transmission function and a reception function. The transmission function is configured to store programs, data and the like. ROM, RAM that temporarily stores data and is used as a working area, CPU that executes programs based on the clock supplied from the crystal oscillator circuit, and 12 is data that can be exchanged with other devices via a cable. A microcomputer board having a serial communication unit for communication, 13
Is a loop antenna (reception means, transmission means) that emits and receives radio waves, 14 is a coupling circuit (reception means, transmission means) of the read / write device 11, and 15 is a communication buffer.

Reference numeral 16 is a modulator (transmitting means) for performing modulation by BPSK (Binary Phase Shift Keying) on the signal output from the communication buffer 15 for temporarily storing communication data, and 17 is this modulation. It is an output amplifier (transmitting means) that amplifies the communication data and outputs it to the coupling circuit 14. Reference numeral 18 is a reception amplifier (reception means) for amplifying the reception signal output from the coupling circuit 14, 19 is a limit (reception means), and 20 is demodulation of the reception signal after the limit 19 is converted into a rectangular waveform of a predetermined level. A demodulation circuit (reception means) 21 for performing the above and outputting to the communication buffer 15, 21 is a power supply unit.

Reference numeral 50 is a variable threshold circuit provided between the receiving amplifier 18 and the limit 19. The output of the preamplifier 51 is a positive input of an operational amplifier (rectifying means) 53 via a resistor (rectifying means) 52. The negative input terminal of the operational amplifier 53 is connected to the terminal and is grounded via a resistor (rectifying means) 54.
The output of the preamplifier 51 is connected to the plus input terminal of a comparator (comparing means) 56 via a resistor 55. A diode (rectifying means) 57 and a resistor (rectifying means) 5 are provided between the output of the operational amplifier 53 and the positive input terminal.
8, a resistor (rectifying means) 60, and a diode (rectifying means) 59 are connected.

The output of the diode 57 is a resistor (threshold signal generating means) 61 and a capacitor (threshold signal generating means) 6
2 and a resistor (threshold signal generating means) 63, and is connected to the negative input terminal of the comparator 56.
The output of the diode 59 is connected to the minus input terminal of the comparator 56 via the resistor (threshold signal generating means) 64, the capacitor (threshold signal generating means) 65, and the resistor (threshold signal generating means) 66. .

Next, the operation will be described. First, the carrier wave (a wave in FIG. 7) input from the loop antenna 13 is
A positive and negative rectified signal (wave b in FIG. 7) is obtained through the rectifying means of the preamplifier 51, the resistor 52, the operational amplifier 53, the resistor 54, the diode 57, the resistor 58, the resistor 60, and the diode 59. Next, the positive rectified signal is the resistor 6
1, and after being averaged (c wave in FIG. 7) via the threshold signal generating means of the capacitor 62, the negative rectified signal is averaged via the threshold signal generating means of the resistor 64 and the capacitor 65. (D in FIG. 7). Then, the positive rectified signal and the negative rectified signal are added via the threshold signal generating means of the resistor 63 and the resistor 66.

Therefore, the waveform thus added becomes a threshold (e wave in FIG. 7) and is located near the center of the positive and negative rectified signals (b wave in FIG. 7). Then, the comparator 56 as a comparison means compares the e-wave as the threshold with the carrier a-wave, and outputs a plus waveform when the carrier a-wave becomes larger than the e-wave as the threshold, and the carrier a-wave If it becomes smaller than the e-wave as the threshold, a negative waveform is output. Therefore, the comparator 56 can follow the transmission data of the carrier wave input from the preamplifier 51 and output an accurate digital signal to the demodulation circuit 20 (f wave in FIG. 7).

On the other hand, even if the carrier wave input from the preamplifier 51 becomes minute on the way and the positive and negative rectified signals each have an irregular waveform (a 'wave in FIG. 7), the positive and negative rectified signals are accordingly responsive. Since the e waves as thresholds are always located near the center of the positive and negative rectified signals, the comparator 56 must follow the transmission data of the carrier wave input from the preamplifier 51 and output an accurate digital signal. Can be generated (f 'wave in FIG. 7).

As described above, according to the first embodiment, the threshold can be changed so as to be located at the center of the carrier wave a, even when the noise of the positive or negative DC component comes in. Therefore, it is possible to obtain an effect that the transmission data from the non-contact IC card 1 can be accurately read even when the noise of the positive or negative DC component comes in.

Embodiment 2 3 is a block diagram showing a part of a non-contact IC card data access device according to a second embodiment of the present invention, and FIG. 8 is a waveform showing a waveform of each part of the non-contact IC card data access device of FIG. It is a figure. In the figure, 70 is a variable threshold circuit corresponding to the variable threshold circuit 50 of FIG. 2, and the output from the preamplifier 71 is a resistor (threshold signal correction means).
It is connected via 72 to the plus input terminal of an operational amplifier (threshold signal correction means) 73 which maintains a duty cycle of 50%. The output of the operational amplifier 73 is feedback-connected to the plus input terminal of the operational amplifier 73 via a resistor (threshold signal correction means) 74, and also the minus input terminal of the operational amplifier 73 via a resistor (threshold signal correction means) 75. Connected to the feedback. The output of the operational amplifier 73 is passed through a low-pass filter (threshold signal correction means) 76 and a resistor (threshold signal correction means) 77, and the operational amplifier 7 is output.
It is feedback-connected to the negative input terminal of 3.

Next, the operation will be described. First, the carrier wave (a wave in FIG. 8) input from the loop antenna 13 is
When input to the plus input terminal of the operational amplifier 73 as the zero-cross detector circuit via the preamplifier 71 and the resistor 72, a pulse waveform (b wave in FIG. 8) is output. Then, by inputting this pulse waveform into the low-pass filter 76, the waveform of the DC component (c in FIG. 8) is obtained.
Wave) and input it to the negative input terminal of the operational amplifier 73. At this time, if the output waveform of the operational amplifier 73 is more positive in time, the low-pass filter 7
The output waveform of 6 is moved to the positive output side so that the output level input to the negative input terminal of the operational amplifier 73 works in the positive direction.

As a result, the output of the operational amplifier 73 goes to the output side in the negative direction and then to the output side in the negative direction.
The duty ratio of the pulse waveform output from 3 can be maintained at 50%. Then, the waveform in which the duty ratio of this pulse waveform is maintained at 50% is output to the demodulation circuit 20 as the output from the operational amplifier 73.

On the other hand, when the output waveform of the operational amplifier 73 has more negative output in time, the output waveform of the low-pass filter 76 is moved to the negative output side, and the output level input to the negative input terminal of the operational amplifier 73 is negative. Work in the direction.

As a result, the output of the operational amplifier 73 has a negative output and shifts to the positive output side.
The duty ratio of the pulse waveform output from 3 can be maintained at 50%. Then, the waveform in which the duty ratio of this pulse waveform is maintained at 50% is output to the demodulation circuit 20 as the output from the operational amplifier 73.

As described above, according to the second embodiment, even if the output level of the carrier wave input to the operational amplifier 73 varies, the duty ratio of the pulse waveform output from the operational amplifier 73 can be maintained at 50%. Therefore, it is possible to obtain the effect that the transmission data from the non-contact IC card 1 can be accurately read even when the noise of the positive or negative DC component comes in.

Embodiment 3 4 is a configuration diagram showing a non-contact IC card data access device according to a third embodiment of the present invention, and FIG. 9 is a waveform diagram showing waveforms of respective parts of the non-contact IC card data access device of FIG. . In the figure, reference numeral 81 is a multiplier (waveform correction means) having an AGC (automatic gain control) function, and the output of the multiplier 81 is input to the input terminal of the variable threshold circuit 50 of the first embodiment. . And, to the first input terminal X of this multiplier 81,
A carrier wave which is received data is input via a capacitor (waveform correction means) 82 and a resistor (waveform correction means) 83. Further, the negative rectified signal from the variable threshold circuit 50 is input to the second input terminal Y of the multiplier 81 via the variable terminal of the variable resistor (waveform correction means) 84. The terminal 85 of the variable resistor 84
A positive voltage (not shown) is applied to.

Next, the operation will be described. First, when a normal carrier as shown by the wave a in FIG. 9 is input from the loop antenna 13 to the first input terminal X of the multiplier 81, the variable input to the second input terminal Y of the multiplier 81 is changed. A negative rectified signal as shown by the wave b in FIG. 9 is input from the threshold circuit 50, and a waveform of a wave × (V−b wave) is output from the output terminal of the multiplier 81. In this case, the voltage levels of the V and b waves cancel each other out and become 0, so that the same waveform as the a wave of FIG. 9 is output. When this waveform is input to the variable threshold circuit 50, a pulse wave as shown by the d wave in FIG. 9 is output as described in the first embodiment.

On the other hand, when an illegal carrier wave whose voltage level is disturbed as shown by the a'wave in FIG. 9 is input from the loop antenna 13 (see FIG. 1) to the first input terminal X of the multiplier 81, , A negative rectified signal having a low negative voltage level is input to the second input terminal Y of the multiplier 81 from the variable threshold circuit 50 at a portion where the output level is low, as shown by the b'wave in FIG. And the multiplier 81
From the output terminal of the a-wave × (V-b
Wave) waveform is output. This output waveform is the same as the c wave in FIG.

As described above, according to the third embodiment, the carrier wave input to the input terminal side of the variable threshold circuit 50 is corrected according to the negative rectified signal of the variable threshold circuit 50. Therefore, even if noise of positive or negative DC component comes in, the contactless I
The effect that the transmission data from the C card 1 can be accurately read is obtained.

Fourth Embodiment 5 is a configuration diagram showing a data access device for a non-contact IC card according to a fourth embodiment of the present invention, and FIG. 10 is a waveform diagram showing waveforms of respective parts of the data access device for a non-contact IC card shown in FIG. . The read / write device 11 according to the first to third embodiments
The transmission / reception circuit of is capable of following the minute output radio wave even if the output radio wave of the non-contact IC card 1 is minute. On the other hand, in the fourth embodiment, when the output radio wave of the non-contact IC card 1 is very small, the output of the sine wave for power supply from the read / write device 11 is increased to make the non-contact IC card 1 Is designed to increase the output of the output radio wave.

Next, the operation will be described. The carrier wave input from the loop antenna 13, which is a receiving antenna, is input to the input terminal of the variable threshold circuit 50 of the first embodiment via the bandpass filter 91 and the preamplifier 92. Then, the negative rectified signal from the variable threshold circuit 50 is input to the second input terminal Y of the multiplier 101 provided on the transmission side via the variable resistor 93. The variable resistor 93
A positive voltage is applied to the terminal 94 of the.

On the other hand, the transmission data from the modulator 16 is input to the first input terminal X of the multiplier 101 via the capacitor 102 and the resistor 103. The output level of the transmission data is corrected according to the voltage level of the negative rectified signal from the variable threshold circuit 50. That is, when the carrier wave as the transmission data of the non-contact IC card 1 input to the input terminal of the variable threshold circuit 50 has an incorrect waveform in which the voltage level is disturbed as shown by the wave a in FIG. The negative rectified signal from the variable threshold circuit 50 has a low negative voltage level at a portion with a low output level, as shown by the c wave in FIG.
It becomes a waveform.

Therefore, in the multiplier 101,
The transmission data shown in the d wave of FIG. 10 input to the first input terminal X is multiplied by the negative rectified signal from the variable threshold circuit 50, and the output as shown in the e wave of FIG. The correction is performed so that the voltage level of the transmission data becomes large at the low level portion. Then, the corrected transmission signal is amplified through the output amplifier 104 and output from the loop antenna 13 which is a transmission antenna.

As described above, according to the fourth embodiment, when the output radio wave of the non-contact IC card 1 is very small, the sine wave for power supply from the read / write device 11 is output. The contactless IC card 1 is designed to have a large size and the output radio wave of the contactless IC card 1 to be large.
The effect that the communication range with can be expanded can be obtained.

Embodiment 5. 6 is a block diagram showing a data access device for a non-contact IC card according to a fifth embodiment of the present invention, and FIG. 11 is a waveform diagram showing waveforms of respective parts of the data access device for a non-contact IC card shown in FIG. . In the figure, the same reference numerals as those in the first to fourth embodiments indicate the same or corresponding portions, and thus the description thereof will be omitted. In the figure, when the transmission data from the non-contact IC card 1 is read and processed as in the third embodiment, the switch 125 is connected to f ₀ and the switch 113 is connected to the terminal 11.
4 by connecting the contactless IC card 1 to the first input terminal X of the multiplier (testing means) 121.
The transmission data f ₀ from the capacitor 12 is the test means.
2. Input via the resistor (test means) 123. On the other hand, the negative rectified signal from the variable threshold circuit 50 is input to the second input terminal Y of the multiplier 121 via the variable terminal of a variable resistor (not shown).

When a self-test for judging whether or not the transmission data from the non-contact IC card 1 can be correctly received, the switch 125 is connected to 3 / 2f ₀ , By connecting the switch 113 to the variable resistor 112, the sine wave of 3 / 2f ₀ created by the microcomputer board 12 is applied to the first input terminal X of the multiplier 121 by the capacitor 122 and the resistor 1.
It is input via 23. On the other hand, the multiplier 121
The second input terminal Y is supplied with the transmission test data of the frequency f ₀ created by the microcomputer board 12 via the output amplifier 17, the capacitor 111, the variable resistor 112, and the changeover switch 113.

The output of the multiplier 121 is input to the microcomputer board 12 via the bandpass filter (test means) 124, the variable threshold circuit 50, and the demodulator 20. The read / write device 11 simultaneously transmits and receives a transmission signal and a reception signal with one loop antenna. However, the frequency F of the reception signal is F / 2, which is half the frequency of the transmission signal, so as not to confuse them. I am trying.

Next, the operation will be described. The wavelength signal (wave a in FIG. 11) of 2 / 3f of the frequency of the transmission test data is input to the first input terminal X of the multiplier 121, and the frequency f is transmitted to the second input terminal Y of the multiplier 121. Enter the test data (wave b in Figure 11),
AM modulation occurs and 5f / 2 is applied to the waveform signal of frequency f / 2.
The waveform signal (c wave in FIG. 11) on which the waveform signal of FIG. When a waveform signal in which a waveform signal of 5f / 2 is superimposed on the waveform signal of frequency f / 2 is passed through the bandpass filter 124, a waveform signal of frequency f / 2 only (d wave in FIG. 11)
Then, the pulse waveform (e wave in FIG. 11) can be converted by passing through the variable threshold circuit 50.

Then, it is input to the microcomputer board 12 via the demodulator 20. Then, the microcomputer board 12 compares the content of the output transmission test data with the content of the received transmission test data to determine whether or not the transmission data from the non-contact IC card 1 can be correctly received. You can make your own judgment.

As described above, according to the fifth embodiment, it is possible to judge whether or not the transmission data from the non-contact IC card 1 can be correctly received, so that the reliability is improved. The effect that can be obtained is obtained.

[0055]

As described above, according to the first aspect of the invention, when the power signal is received by the transmitting means, the drive state is transited, and when the read signal is received, the data stored in the memory is transmitted. While transmitting the power signal and the read signal to the contact IC card, the positive rectified signal and the negative rectified signal output from the rectifying means by the threshold signal generating means are added to each other, and the addition result is output as the threshold signal. Since it is configured to do so, there is an effect that the transmission data from the non-contact IC card can be accurately read even when the noise of the positive or negative DC component comes in.

According to the second aspect of the present invention, when the power signal is received by the transmitting means, it transits to the drive state and the read
When the write signal is received, the data stored in the memory is transmitted, and the power signal and the read / write signal are transmitted to the non-contact IC card storing the data in the memory, while the threshold signal generating means rectifies the data. Since the positive rectified signal and the negative rectified signal output from the means are added to each other and the addition result is output as the threshold signal, even if noise of the positive or negative DC component comes in There is an effect that the transmission data from the contact IC card can be accurately read.

According to the third aspect of the invention, the positive and negative rectified signals are smoothed, and the smoothed positive rectified signal and negative rectified signal are added to each other.
Even if noise of a positive or negative DC component comes in, there is an effect that the transmission data from the non-contact IC card can be accurately read.

According to the invention described in claim 4, when the waveform correction means increases the amplitude of the data received by the reception means when the absolute value of the negative rectified signal is smaller than the predetermined value, the positive value is obtained. Alternatively, even when noise of a negative DC component comes in, the transmission data from the non-contact IC card can be accurately read.

According to the fifth aspect of the present invention, when the power signal is received by the transmitting means, the state is changed to the driving state, and when the read signal is received, the non-contact IC card which transmits the data stored in the memory is transmitted. The power signal and the read signal are transmitted, the data received by the receiving means is compared with the threshold signal by the comparing means, a pulse signal is output according to the comparison result, and the pulse output from the comparing means by the threshold signal correcting means. The positive side pulse width of the signal is compared with the negative side pulse width, and when the positive side pulse width is larger than the negative side pulse width, the above threshold signal is increased to the positive side, while the positive side pulse width is negative. Since the threshold signal is increased to the negative side when the pulse width is smaller than the pulse width on the side, the transmission data from the non-contact IC card will be accurate even when noise of positive or negative DC component comes in. There is an effect that can be read.

According to the sixth aspect of the invention, when the power signal is received by the transmitting means, the drive state is transited to,
When the write signal is received, the data stored in the memory is transmitted, and the power signal and the read / write signal are transmitted to the non-contact IC card storing the data in the memory, and the comparing means receives the receiving signal. The generated data is compared with a threshold signal, a pulse signal is output according to the comparison result, and the positive pulse width and the negative pulse width of the pulse signal output from the comparison means by the threshold signal correction means are compared. When the positive pulse width is larger than the negative pulse width, the threshold signal is increased to the positive side, while when the positive pulse width is smaller than the negative pulse width, the threshold signal is increased to the negative side. Since it is configured as described above, there is an effect that the transmission data from the non-contact IC card can be accurately read even when the noise of the positive or negative DC component enters.

According to the seventh aspect of the invention, when the rectifying means and the threshold signal generating means are tested, a signal having a frequency that is ⅔ times the frequency of the read signal or the read / write signal and a negative rectified signal are used. In addition to the multiplication, a read signal or a signal having a frequency that is half the read / write signal is extracted from the multiplication result, and the extracted signal is used as the data received by the receiving means. There is an effect that the reliability can be improved.

According to the invention described in claim 8, since the power signal level is determined based on the reception level of the data received by the receiving means, the communication range with the non-contact IC card can be widened. There is an effect that can be.

[Brief description of the drawings]

FIG. 1 is a configuration diagram showing a data access device for a non-contact IC card according to a first embodiment of the present invention.

FIG. 2 is a configuration diagram showing a part of a data access device for a non-contact IC card according to the first embodiment of the present invention.

FIG. 3 is a configuration diagram showing a part of a non-contact IC card data access device according to a second embodiment of the present invention.

FIG. 4 is a configuration diagram showing a part of a data access device for a non-contact IC card according to a third embodiment of the present invention.

FIG. 5 is a configuration diagram showing a part of a data access device for a contactless IC card according to a fourth embodiment of the present invention.

FIG. 6 is a configuration diagram showing a part of a data access device for a non-contact IC card according to a fifth embodiment of the present invention.

7 is a waveform diagram showing waveforms of respective parts of the data access device for the non-contact IC card shown in FIG.

8 is a waveform diagram showing waveforms of respective parts of the data access device for the non-contact IC card shown in FIG.

9 is a waveform diagram showing waveforms of respective parts of the data access device for the non-contact IC card in FIG.

10 is a waveform diagram showing waveforms of respective parts of the data access device for the non-contact IC card shown in FIG.

11 is a waveform diagram showing waveforms of respective parts of the data access device for the non-contact IC card shown in FIG.

FIG. 12 is a configuration diagram showing a configuration of a conventional non-contact IC card data access device.

13 is a system diagram showing functions of the non-contact IC card data access device shown in FIG.

FIG. 14 is a circuit diagram specifically showing the coupling circuit described in FIG.

15 is a waveform chart showing the threshold level when an incorrect waveform is input to the coupling circuit of FIG.

[Explanation of symbols]

1 non-contact IC card, 13 loop antenna (reception means, transmission means) 14 coupling circuit (reception means, transmission means),
16 modulator (transmitting means), 17 output amplifier (transmitting means), 18 receiving amplifier (receiving means), 19 limit (receiving means), 20 demodulating circuit (receiving means), 52, 5
4, 58, 60 resistor (rectifying means), 53 operational amplifier (rectifying means), 56 comparator (comparing means), 5
7,59 Diodes (rectifying means), 61,63,6
4,66 resistors (threshold signal generating means), 62,65
Capacitors (threshold signal generating means), 72, 74, 75,
77 resistors (threshold signal correction means), 73 operational amplifiers (threshold signal correction means), 76 low-pass filters (threshold signal correction means), 81 multipliers (waveform correction means), 82 capacitors (waveform correction means), 83 resistors ( Waveform correction means), 84 Variable resistor (waveform correction means), 121 Multiplier (test means), 122
Capacitor (testing means), 123 Resistor (testing means), 124 Bandpass filter (testing means).

Claims (8)

[Claims] 1. A transmission means for transmitting the power signal and the read signal to a non-contact IC card that transits to a driving state when receiving the power signal and transmits the data stored in the memory when receiving the read signal. And the above non-contact I
Receiving means for receiving data transmitted from the C card,
Rectifying means for rectifying the data received by the receiving means and outputting a positive and negative rectified signal, and a positive rectified signal and a negative rectified signal output from the rectifying means are added together, and the addition result Of a non-contact IC card provided with a threshold signal generating means for outputting as a threshold signal, and a comparing means for comparing the data received by the receiving means with the threshold signal and outputting a pulse signal according to the comparison result. Data access device. 2. When a power signal is received, a transition is made to a driving state, and when a read / write signal is received, the data stored in the memory is transmitted, and a non-contact IC card that stores the data in the memory, Transmitting means for transmitting the power signal and read / write signal, receiving means for receiving the data transmitted from the non-contact IC card, and rectifying the data received by the receiving means,
Rectifying means for outputting positive and negative rectified signals, threshold signal generating means for adding the positive and negative rectified signals output from the rectifying means to each other, and outputting the addition result as a threshold signal, A data access device for a non-contact type IC card, comprising: comparison means for comparing the data received by the reception means with the threshold signal and outputting a pulse signal according to the comparison result. 3. The threshold signal generating means smoothes the positive and negative rectified signals, and adds the smoothed positive rectified signal and the negative rectified signal to each other. 2. A non-contact IC card data access device according to 2. 4. The waveform correction means for increasing the amplitude of the data received by the receiving means when the absolute value of the negative rectified signal is smaller than a predetermined value.
4. The data access device for a non-contact IC card according to claim 3. 5. A transmitting unit that transmits the power signal and the read signal to a non-contact IC card that transits to a driving state when receiving the power signal and transmits the data stored in the memory when receiving the read signal. And the above non-contact I
Receiving means for receiving data transmitted from the C card,
Comparison means for comparing the data received by the receiving means with a threshold signal and outputting a pulse signal according to the comparison result, and a pulse width on the positive side and a pulse on the negative side of the pulse signal output from the comparing means. When the positive side pulse width is larger than the negative side pulse width, the threshold signal is increased to the positive side while the positive side pulse width is smaller than the negative side pulse width. A data access device for a non-contact IC card, comprising a threshold signal correction means for increasing the value on the negative side. 6. When a power signal is received, a transition is made to a driving state, and when a read / write signal is received, the data stored in the memory is transmitted, and the non-contact IC card that stores the data in the memory is Transmitting means for transmitting the power signal and read / write signal, receiving means for receiving the data transmitted from the non-contact IC card, and data received by the receiving means are compared with a threshold signal, and the comparison result is obtained. According to the comparison means for outputting a pulse signal and the pulse width on the positive side and the pulse width on the negative side of the pulse signal output from the comparison means are compared, and the pulse width on the positive side is less than the pulse width on the negative side. And a threshold signal correction means for increasing the threshold signal to the negative side when the pulse width on the positive side is smaller than the pulse width on the negative side. Non-contact IC card data access device. 7. When testing the rectifying means and the threshold signal generating means, a signal having a frequency that is ⅔ the frequency of a read signal or a read / write signal is multiplied by a negative rectified signal, and the multiplication result is used. 2. A test means for extracting a signal having a frequency that is half the read signal or a read / write signal and using the extracted signal as the data received by the receiving means. Item 6
A data access device for a non-contact IC card according to any one of the above. 8. The transmission means determines the level of the power signal based on the reception level of the data received by the reception means, as claimed in any one of claims 1 to 7. Non-contact IC card data access device.