JPS60225289A - Ic card - Google Patents

Abstract

PURPOSE:To make it possible to stand an electric shock such as static electricity by supplying power source by irradiating light for a card power source part from a light source and transferring a signal with a light signal. CONSTITUTION:When an IC card 20 is inserted into a card insertion port of a card reader 36, the card reader 36 irradiates light for a power source 26 of the IC card 20 from a light source 44 and causes an electromotive force to generate at a solar cell of the card power source part 26. When an oscillating signal Xtal, which is outputted from an oscillator 41 at the side of the card reader 36, is supplied through a light emitting element 421a to a light receiving element 23a of the IC card 20, a CPU221 starts to operate and reads out necessary items from a data store part 222. Read data Out are converted to a light signal by a light emitting signal 24 and is transmitted to the card reader 36. The data Out is received at a photodetector 422, is transmitted to a CPU431, is sent to an external device and is read.

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to an IC card having a built-in integrated circuit data storage device, which is particularly capable of withstanding electric shocks caused by static electricity, etc., and is capable of resisting unauthorized attempts such as rewriting memory contents by the card user. The present invention relates to an improved card that can prevent such problems and has a driving power source in the card itself.

In recent years, magnetic cards have rapidly become popular in various fields, including the financial and distribution fields, due to their labor-saving systems using computers. Therefore, in the above-mentioned magnetic cards, it is becoming insufficient to check the electrical code using a magnetic stripe or an embossed function or visually check the code.

For this reason, an IC card as shown in FIG. 1 has appeared. This IC card has a substrate 11 made of synthetic resin such as polyester or vinyl chloride, and has a magnetic stripe 12 coated on the surface of the substrate 11, as in the case of the magnetic card described above. It has a built-in integrated circuit as shown in the figure, and has multiple holes (
Here, eight connection electrodes 13a to 13h are exposed and provided.

Here, the integrated circuit is a central processing circuit (CPU)
14 and a memory circuit 15, of which CP Ll 14 is connected to Vcc (5V
) Power supply terminal 13a, ground (GND).

OV) terminal 13b1 Reset terminal 13c
, input/output (Ilo> terminal 13d) and crystal (crystal oscillator, Xtal) terminal 13e, and the memory circuit 15 is connected to the Vpp (25V) program power supply terminal 1.
3f and the GND terminal 13b. In addition, the above c
p U 14 and memory circuit 15 are connected to address data bus 1
6, and is also connected to the electrode 13 (1, 13h
is an unused electrode.

Such an IC card can store more information than conventional magnetic cards, and can maintain confidentiality, thereby improving reliability.

However, current IC cards are not only susceptible to electric shocks such as static electricity generated in connection electrodes, but also introduce noise components through power supply lines and signal transmission lines. Furthermore, if this IC card is used as a bank cash card or the like, fraud may occur due to the card user rewriting the memory contents.

This invention was made to improve the above problems, and is capable of withstanding electric shocks such as static electricity, as well as being able to remove noise components from power supply lines and signal transmission lines. Extremely good I that can prevent fraud due to card user rewriting memory contents
The purpose is to provide C cards.

That is, the IC card according to the present invention has a data storage device formed as an integrated circuit embedded in a card base and exchanges information with a card reader, in which the IC card is embedded in the card base and transmits data from the card reader. a light-receiving element that receives a corresponding optical signal and transmits it to the data storage device; and a light-emitting element that is embedded in the card base and converts a data ladder signal output from the data storage device into an optical signal and transmits the optical signal to the card reader. , a driving power source embedded in the card base and generating a driving voltage for the data storage device, the light receiving element, and the light emitting element; in particular, the driving power source is configured using a solar cell. It is characterized by this.

Hereinafter, one embodiment of the present invention will be described in detail with reference to FIGS. 3 to 5.

Fig. 3 shows its schematic configuration, Fig. 3(a) is a top view of the IC card 20, and Fig. 3(b) is a cross-sectional view taken along line A-A in Fig. 3(a). A cross-sectional view is shown. That is, this IC card 20 includes an integrated circuit that forms a CPU 221 and a data store section 222 constituting a data storage device on the left side in the figure inside a base body 21 made of synthetic resin such as polyester or vinyl chloride. 22. First to third light receiving elements (here) i l-l for receiving a crystal oscillation signal Xtal, a data input signal 1 n, and a reset 1 to signal Reset sent as optical signals from a card reader, which will be described later. ~Langister) 23a~
23C1 Light emitting element (here, a light emitting diode) 2 for converting the data output signal □ut from the data storage device (integrated circuit) 22 into an optical signal and outputting it to the card reader.
4 is buried in a predetermined position, and an opaque plastic layer 25 such as a polyester film is formed on the surface of the plastic layer 25.
form. Also, on the right side of the figure inside this card base 21, there are a plurality of (six in this case) solar cells 268 to 268.
26f are arranged in parallel, and a card power supply section 26 having a voltage generation source connected in series is embedded, and a transparent plastic layer 2 such as a polyester film is placed on the surface of the card power supply section 26.
7. In other words, the buried portions of the light-receiving elements 23a to 23c and the light-emitting element 24 are designed so that they cannot be seen with the naked eye, for example, so that only light in the infrared region to which the light-receiving elements 22a to 22c are sensitive are transmitted. The buried portion of the portion 26 is configured to receive light from the outside.

FIG. 4 shows the structure of the buried portion of the card power supply section 26. FIG. 4(a) is a top view thereof, and FIG. 4(b) is a cross-sectional view taken along line B-B in FIG. 4(a). This shows a cross-sectional view when That is, each solar cell 26a to 26f of this card power supply section 26 is connected to a stainless steel substrate 28a to 28f, respectively.
N-type amorphous silicon layers 29a to 29f1 intrinsic amorphous silicon layers 30a to 30f on 28f
, I) Type amorphous silicon layers 31a to 3R and transparent electrode layers 32a to 32f are formed by sequentially stacking them,
Between each cell 26a-2Bf, conductive films 34a-33e are used to prevent conduction between the respective layers.
34e connects adjacent transparent electrode layers 32a to 32e and stainless steel substrates 28b to 28f. Power supply electrodes 35a and 35b formed by vapor deposition of aluminum are wired to the stainless steel substrate 28a of the cell 26a on both sides and the transparent electrode layer 32f of the cell 26f, respectively. These power supply electrodes 35a and 35b are connected to a driving voltage Vpp and a data rewriting voltage Vc (not shown).
It is connected to a voltage conversion circuit for converting the voltage. That is, in this card power supply section 26, the solar cell 2
The power generated by the voltage generation sources 6a to 26f is converted into a driving voltage Vpp and a data rewriting voltage Vcc by the voltage conversion circuit, and the integrated circuit 22 and the light receiving element 23
a to 23c and the light emitting element 24.

FIG. 5 shows the circuit configuration of the IC card 20 and the card reader 36 for this IC card, in which the integrated circuit 22 is connected to the CPU 221. The data store section 222, resistors R1 to R7, and signal amplifiers Op1 to Op3 constitute the data store section 222, and the drive voltage Vpp and the data rewriting voltage Vcc are inputted from the card power supply section 26, and the Vpp voltage is applied to the data store section 222. and supply the Vcc voltage to the resistor R
1 to R4 and the CPU 221.

At this point, the CPU 221 receives the crystal oscillation signal Xtal, the data input signal 1n, and the reset signal R received by the first to third light receiving elements 23a to 23C.
esf3t are resistors R5 to R7 and signal amplifier O, respectively.
It is configured to be supplied via pl to Op3,
It is also connected to the data store section 222 through an address bus 223, a data bus 224, and a control bus 225. The CPU 221 then uses the data store unit 22
The data written in the card reader 2 is read and supplied to the light emitting element 24, and the data is transmitted to the card reader 36.

The data store section 222 is an electrically rewritable E-EPROM (E-EPROM).
rasable programmable Re
adOnlyMemorV). Further, the light receiving elements 23a to 230 and the light emitting element 24 are supplied with Vc c 'R pressure via the resistors R1 to R4.

For such an IC card 20, the card reader 36 has connection terminals 39a and 33b for inputting and outputting control signals to an external device (not shown) and connection terminals for inputting and outputting data to this external device. It has 39c. Inside, there is a reader power supply unit 40, an oscillator 4
1. IC card transmitting/receiving circuit 42, arithmetic unit 43, and light source 4
4 are configured.

Here, the reader power supply unit 40 includes the oscillator 41, I
It supplies a voltage to the C card transmitting/receiving circuit 42, arithmetic unit 43, and light source 44. In addition, the oscillator 41
generates a crystal oscillation signal xtal for controlling the operation of the CPU 221 of the IC card.

The IC card transmitting/receiving circuit 42 includes first to third light emitting elements (here, light emitting diodes) 421a to 421a.
21c1 light receiving element (phototransistor here) 42
2, resistors R8 to R12, and a signal amplifier Op4, and the driving voltage from the reader power supply section 40 is applied to the resistor R8
The light is supplied to the light emitting elements 421a to 421C and the light receiving element 422 via R11. and,
The first to third light emitting elements 421a to 421C each receive an oscillation signal ×tal from the oscillator 41 and a calculation unit 4.
Data signal from 3 (IC card input data>rn,
A reset signal R6set is supplied, each of which is converted into an optical signal and transmitted to the IC card 20. Further, the light receiving element 422 is connected to the IC card 2
Data signal from 0 (IC card output data) Qut
is received and output to the arithmetic unit 43 via the resistor R12 and the signal amplifier Op4.

This calculation NI43 is C; PU431, P-ROM4
32, RAM 433, first PSI (serial data transmission/reception interface) 434, second PSI 435, PP
An I (parallel data transmission/reception interface) 436 is provided, and each circuit 431 to 436 is connected via an address bus 43γ and a data bus 438.1llJ control bus 439. Here, the CPU 431 controls the mechanical section and the control section (none of which are shown) of the card reader 36, and sends the data signal (n and reset signal Reset) to the IC card 20 as described above. The P-ROM 432 controls the entire system by instructing the first PSI 434 and receiving the data signal □ut from the rC card 20.
31 is stored therein. The RAM 433 is the card reader 36
It is used for data processing, exchanging data between the computer and external devices.

Furthermore, the first PSI 434 is for exchanging data with the IC card 20, and the second PSI 434
435, the above connection terminals 39a and 39b are connected,
These connection terminals 39a and 39b are used to send and receive serial data to and from external devices connected to the PPI 43 mentioned above.
Reference numeral 6 is connected to the connection terminal 39c via a data bus 45, and transmits and receives parallel data to and from an external device connected to this connection terminal 39c.

The light source 44 irradiates the power supply unit 26 with light when the IC card 2o is set.

The operation of the above configuration will be described below.

First, when the IC card 20 with various data input is inserted into the card insertion slot of the card reader 36, the card reader 36 is activated by the optical system. 1i44 irradiates the IC card 20 (7) power supply section 26 with light to generate an electromotive force in the solar cells 26a to 26'' of the card power supply section 26.

As a result, in the IC card 20, the driving voltage Vcc and the data writing voltage VPP are generated from the electromotive force and supplied to each circuit section, so that all the circuit sections in the IC card 20 are set to the driving state. will be done.

Here, when reading the data stored in the data store section 222, the oscillator 41 on the card reader 36 side
When the oscillation signal Xtal output from the IC card 20 is supplied to the light receiving element 23a of the IC card 20 via the light emitting element 421a,
The CP Ll 221 starts operating and the data store section 2
The necessary items are read from 22. The data Qut read by the CPU 221 is converted into an optical signal by the light emitting element 24 and transmitted to the card reader 36. The read data Qut sent to the card reader 36 is received by the light receiving element 422 and supplied to the PSI 434, and is further supplied to the address bus 437, data bus 438 and control bus 4.
39 to the CPU 431. and,
Due to the operation of this CP Ll 431, the read data is transferred to the connection terminal 3 via the PSI 435 and PPI 436.
9a to 39c, and are sent to an external device and read.

Next, when writing new data to the data store section 222, a data write control signal is output from the CPU 431 of the card reader 36, and the P-ROM 432 and RA
By the action of M 433, the write control signal (=In) is supplied to the light emitting element 421b through the PSI 434, and sent to the IC card 20 as an optical signal.

In response, the IC card 20 receives the optical signal with the light receiving element 23b and supplies it to the CPU 221.
The Ll 221 is set to a write control state and necessary data is written to the data store section 222. At the same time as this data writing is completed, the CPLI431 of the card reader 36
, P due to the action of P-ROM432 and RAM433
Reset signal Rese sent from P I 436
t to the IC via the light emitting element 421C1 and the light receiving element 23c.
This CPU is supplied to the CPU 221 of the card 20.
By resetting U 221, the writing of the data is completed.

That is, the IC card 20 is powered by the light source 44.
This is done by irradiating light onto the card power supply unit 26 from the source, and the transmission and reception of signals to and from the card reader 36 is performed using optical signals sent to the light receiving elements 23a to 23C and the light emitting element 24.

Therefore, the IC card 20 configured as described above is
Since the power supply section 26 generates an electromotive force internally and the signal transmission line is configured to send and receive optical signals, it can be made extremely resistant to static noise, thereby preventing electric shocks such as static electricity. can withstand. Furthermore, by embedding the light-receiving elements 23a to 23c and the light-emitting element 24 in the card base 21, security is extremely high against unauthorized data rewriting by the user.

As detailed above, according to the present invention, in an IC card in which a data storage device formed as an integrated circuit is embedded in a card base and exchanges information with a card reader, the data storage device embedded in the card base is a light receiving element that receives an optical signal corresponding to a transmitted data signal and transmits it to the data storage device; and a card reader that is embedded in the card base and converts the data signal output from the data storage device into an optical signal. a light-emitting element for transmitting data to the card; and a driving power source embedded in the card base and generating a driving voltage for the data storage device, the light-receiving element, and the light-emitting element, and the driving power source is configured using a solar cell. As a result, it is possible to withstand electric shocks such as static electricity, remove noise components from power supply lines and signal transmission lines, and prevent fraud by card users from rewriting memory contents. An extremely good IC card can be provided.

[Brief explanation of the drawing]

FIG. 1 is a top view showing the external configuration of a conventional IC card, FIG. 2 is a block circuit diagram showing the internal circuit of the IC card, and FIGS. 3 to 5 are an embodiment of the IC card according to the present invention. 3(a) and (b) are a top view and a cross-sectional view showing the configuration of the above embodiment, respectively, and FIG. 4(a)
, (b) are a top view and a sectional view showing the configuration of the IC card power supply section of the above embodiment, respectively, and FIG.
FIG. 2 is a block circuit diagram showing a card internal circuit and a card reader circuit for this IC card. 20...IC card, 21...card base, 22.
・Integrated circuit, 221 ・CP tJ, 222 ・
...Data store section, 23a to 23c... Light receiving element,
24... Light emitting element, 26... Card power supply section, 26a
~26f... Solar battery cell, 36... Card reader, 40... Reader power supply section, 41... Oscillator, 42...
・・IC card transmitting/receiving circuit, 43 ・Calculating unit, 44・
··light source. Applicant Sub-Agent Patent Attorney Takehiko Suzue Figure 1 Figure 2 Figure 3 (a) 6 (b) 6 Figure 4 (a)

Claims (2)

[Claims] (1) In an IC card in which a data storage device formed as an integrated circuit is embedded in a card base and exchanges information with a card reader, the optical signal embedded in the card base corresponds to a data signal transmitted from the card reader. a light-receiving element that receives data and transmits it to the data storage device; a light-emitting element embedded in the card base that converts a data signal output from the data storage device into an optical signal and transmits the optical signal to a card reader; An IC card comprising: an embedded data storage device; and a drive power source that generates drive voltages for a light receiving element and a light emitting element. (2) The IC card according to claim 1, wherein the driving power source is constructed using a solar cell.