JPS63182796A - Interface for optical card containing ic - Google Patents

Abstract

PURPOSE:To improve service performance and the commercial activity by using a transmission means which performs the transfer of data and the supply of power to an external device for optical card with no contact. CONSTITUTION:An optical card 1 contains a power supply coil 2 which receives and supplies the power via an external device 10 like an optical card driver, etc., by the inductive connection, a receiving photodetector 3 which exchanges information by the optical communication, and a light emitting element 4 for transmission of information on the data, etc., set on a single side of the card 1. The device 10 contains a power supply coil 11 corresponding to the coil 2, a transmitting light emitting element 12 corresponding to the photodetector 3, and a receiving photodetector 13 corresponding to the element 4 respectively. In such a constitution, a connector is omitted so that a thin and light-weight card 1 is obtained. In addition, no defective contact is produced since no connecting part is provided and therefore the reliability is improved.

Description

[Detailed Description of the Invention] (Industrial Application Field) The present invention relates to an interface for an optical card equipped with an IC,
In particular, the present invention relates to an interface for an IC-mounted optical card in which an optical recording medium and an IC memory are mounted on one card.

[Conventional technology]

In recent years, there have been systems in which a storage medium is mounted on a resin card of the size of a business card and inserted into a terminal device of an online system so that information can be exchanged. A card mounted with a semiconductor memory is called an IC card, and a card mounted with an optical recording medium is called an optical card.

Since IC cards require a line to supply power to the semiconductor elements inside the card and an interface to exchange data, a contact terminal is provided on one side of the card for connection to a terminal device. ing.

On the other hand, optical cards do not require connectors because they are written or read by applying a laser beam to the optical recording medium from the outside.C).

As mentioned above, by using cards that can exchange information, it is possible to print records on passbooks, etc., which were previously required, and to store cash.
It is possible to eliminate the need to bring a seal, etc., and it is possible to improve serviceability and commercial activities.

[Problem that the invention seeks to solve]

However, for cards with conventional memory functions,
Since cards and terminal systems are created for each type of recording medium, no consideration has been given to mutual compatibility or the common use of terminal devices.

On the other hand, it is thought that the future mainstream will be optical memory, which does not require any connectors, is easy to implement, and has a large storage capacity. It is desirable to apply Moreover,
Even if the format is to mount an IC memory, the IC
It is desirable that power supply to the memory and data exchange be possible without contact, without using a connector or the like.

The present invention has been made in view of the above-mentioned circumstances of the prior art.
An object of the present invention is to provide an interface for an IC-mounted optical card that allows data transmission and power supply to the IC memory or the like to be carried out without contact when the IC memory or the like is mounted on the optical card.

[Means for solving problems]

In order to solve the above problems, the present invention provides an optical card equipped with an integrated circuit such as a semiconductor memory together with an optical recording medium, and an external device for the optical card such as an optical card driver that transfers data and supplies power to the integrated circuit. A means of transmission is provided for communication between the two without contact.

[For production]

Data transmission means using light, radio waves, magnetism, etc. and power transmission means using inductive coupling indirectly enable data exchange and power transmission between an optical card and an external device for the optical card.

This enables contactless transmission, making connections using electrodes such as connectors unnecessary.

〔Example〕

Hereinafter, one embodiment of the present invention will be described based on the drawings.

FIG. 1 shows a circuit diagram of an interface according to the present invention, and FIG. 2 is a perspective view showing an IC-mounted optical card.

As shown in FIG. 2, an IC-equipped optical card (hereinafter referred to as an optical card) has a power coil 2 for receiving power by inductive coupling from an external device such as an optical card driver installed in a terminal device. , a receiving photodetector 3 for exchanging information by optical communication, and a light emitting element 4 for transmitting information such as data are arranged on one side. moreover,
Circuits and semiconductor memory connected to these are embedded within the card. On the other hand, an optical recording medium 5 is provided separately from the IC portion on the same side where the light emitting element 4 and the like are provided.

Note that a thin primary or secondary battery (
(not shown) is installed to back up the semiconductor memory. Among these primary or secondary batteries, in the case of a secondary battery, a power supply voltage obtained by rectifying the induced voltage of the power supply coil 2 is supplied. In the case of a primary battery, when an external power supply circuit is connected, the circuit of the primary battery is opened, and when the power supply circuit is not connected, the primary battery is closed.

Furthermore, the wavelengths used by the photodetector 3 and the light emitting element 4 are as follows:
In order to achieve isolation, it is desirable to set different wavelength bands. However, if there is a sufficient distance between them, they may have the same wavelength. Note that when both are disposed at a close distance, isolation can be ensured by adding an optical filter whose passband is the used wavelength to each opening.

As shown in FIG. 1, a power supply coil 2. A power receiving circuit 6 is provided in each of the photodetector 3 and the light emitting element 4.
．． A receiving circuit 7 and a transmitting circuit 8 are each connected.

On the other hand, external devices such as optical card drivers
In this case, power supply coil 1) corresponding to coil 2). A transmitting light emitting element 12 corresponding to the photodetector 3 and a receiving photodetector 13 corresponding to the light emitting element 4 are provided. A power transmission circuit 14 is connected to each of the coil 1) 1 light emitting element 12 and photodetector 13. A transmitting circuit 15 and a receiving circuit 16 are connected.

FIG. 3 is a circuit diagram of an optical communication interface circuit including a light emitting element and a photodetector shown in FIG. 1. Although a combination of the light emitting element 12 and the photodetector 3 is shown here, the combination of the light emitting element 4 and the photodetector 13 also has exactly the same configuration.

The transmitting circuit 15 is constituted by a transistor 151 having a collector connected to the light emitting element 12 using an LED, and the light emitting element 12 is connected to the serially converted "I(" level and "L" level digital data applied to the data terminal e).
turns on and off.

The receiving circuit 7 includes an amplifier 71 that amplifies the photo-electrical output of the photodetector 3 and a comparator 72 that shapes the waveform of the amplified signal.

FIG. 4 is a circuit diagram showing details of the power transmission circuit 14 and power reception circuit 6 shown in FIG. 1.

The power transmission circuit 14 includes an excitation circuit 141 that generates a signal with a fundamental frequency of several hundred KHz, and converts the DC voltage applied to the terminal a into an AC voltage at a frequency given by the excitation circuit 141, and supplies the voltage to the coil 1). Inverter 1 to supply
It consists of 42 pieces.

The power receiving circuit 6 includes a rectifier bridge 61 .
A smoothing capacitor 62 removes ripples included in the output voltage of the bridge 61, and a constant voltage circuit 6 stabilizes the DC output from the rectifier bridge 61 to a desired voltage.
Consists of 3. 'Next, the operation of the configurations shown in FIGS. 1, 3, and 4 will be explained.

When transferring data from an external device 10 such as an optical card driver to the IC circuit of the optical card 1, "H" level and "L" level digital signals converted to serial data are applied to terminal C, and these binary signals are The transistor 151 is switched according to the number. Each time the transistor 151 is turned on, the light emitting element 10 emits light, and this light is received by the photodetector 3 of the optical card 1. The received light output waveform of the photodetector 3 matches data transmitted from an external device 10 such as an optical card driver, and is amplified to a predetermined level by an amplifier 71. After the amplified received light output waveform is waveform-shaped by a comparator, it is outputted to terminal e as received data and used for writing into a semiconductor memory or the like.

The above is a case where data is transferred from the external device 210 such as an optical card driver to the optical card 1.
Data transfer from the host to an external device 10 such as an optical card driver is performed in the same manner. This case can be explained by replacing the light emitting element 12 in FIG. 3 with the light emitting element 4, the photodetector 3 with the photodetector 13, the receiving circuit 7 with the receiving circuit 16, and the transmitting circuit 15 with the transmitting circuit 8.

On the other hand, power is supplied to an external device 1 such as an optical card driver.
On the zero side, the DC voltage is converted into a rectangular wave voltage according to the frequency of the excitation circuit 141, and this high frequency voltage is supplied to the coil 1).

Since the coil 2 of the optical card 1 is arranged opposite to the coil 1), a high frequency voltage of the coil 1) is induced in the coil 2. The voltage induced in the coil 2 is double-wave rectified by the rectifier bridge 61, and the ripple of the rectified output is removed by the smoothing capacitor 62. The rectified DC voltage is stabilized and output to a desired voltage by the constant voltage circuit 63. This voltage is used to charge the secondary battery built into the optical card 1, and is also used as a power source for the IC circuit.

Although data is transmitted and received optically in the above example, a configuration using radio waves or magnetic coupling may also be used. next,
This configuration will be explained.

FIG. 5 shows a non-interface for data transfer using radio waves, and FIG. 6 shows a circuit for a data transfer interface using magnetic coupling.

In FIG. 5, instead of the coils 2 and 1) in FIG. 1, a tuning coil 17 is provided in an external device 10 such as a driver, and a tuning coil 18 is built into the optical card 1. A transmission circuit 19 is connected to the tuning coil 17, and the tuning coil 1
8 is connected to a receiving ε circuit 20.

The transmitting circuit 19 modulates the "H" level of the digital data into a low frequency signal of a specific frequency, converts the frequency of this into a high frequency signal, and outputs the signal from the terminal. The transmitting circuit 19 includes an amplifier 19 that amplifies the signal input to the terminal.
1 and a matching circuit 192 for matching the output circuit of the amplifier 191 to the impedance of the tuning coil 17.

The receiving circuit 20 also includes an amplifying element 201 that amplifies the received output output from the tuning coil 18, and an amplifying element 201 that amplifies the received output output from the tuning coil 18.
It is comprised of a demodulator 202 that demodulates a single output signal and converts it into a binary level digital signal.

In the configuration of FIG. 5, AM modulation (or FM modulation,
After the data signal is power-amplified by an amplifying element 191 (modulation methods such as PM and PCM are also possible), it is supplied to a tuning coil 17 whose impedance is matched by a matching circuit 192, and is radiated as a radio wave. The radio waves from the tuning coil 17 are received by the tuning coil 18, amplified by the amplification element 201, and then returned to the original digital data by the demodulator 202. Note that the configuration shown in FIG. 5 requires two pairs for bidirectional communication. Note that the tuning coils 17 and 18 are commonly used transmitting and receiving antennas.

In FIG. 6, an external device 1 such as an optical card driver is shown.
An electromagnetic coil 21a is provided on the 0 side, and an electromagnetic coil 22b is provided on the optical card 1 side. These electromagnetic coils are used for transmission and reception, and phase modulation is used for data transmission.

In the external device 10 such as an optical card driver, input data is subjected to PM modulation in a PM modulation circuit 22, amplified in an amplifier 23, and then transmitted data is supplied to an electromagnetic coil 21. Further, upon reception, received data electromagnetically induced by the electromagnetic coil 21 is amplified by an amplifier 24 and then demodulated by a phase (φ) detector 25 .

Similarly, the optical card 1 has a transmission system composed of a PM modulation circuit 28 and an amplifier 29, and a reception system composed of an amplifier 26 and a phase detector 27.

In addition, in the above embodiment, the optical card includes an IC circuit,
Although it is assumed that a memory etc. is installed, the interface according to the present invention can also be applied to an IC card. In this way, since the connector can be eliminated, the card can be made thinner and lighter, and there is no connection failure due to the lack of a connection part, and the reliability can be improved. becomes.

〔Effect of the invention〕

As explained above, according to the present invention, it is possible to supply power to the IC circuit section in the card and exchange information without contact without using a connector, and it is possible to reduce the size and weight and improve reliability. As well as optical card and I
It becomes possible to hybridize and share C cards.

In addition, when storing the optical card in the storage case or using the optical card with the optical card stored in the case,
The storage case itself may be provided with the same power supply and information exchange means as external devices such as optical card drivers.

Furthermore, the storage case may be provided with means for supplying power and acting as an intermediary for information exchange between the optical card and an external device such as an optical card driver.

[Brief explanation of the drawing]

FIG. 1 is a block diagram showing an embodiment of the present invention, FIG. 2 is a perspective view showing an IC-equipped optical card according to the present invention, and FIG. 3 is a circuit diagram showing details of the data transfer interface circuit of FIG. 1. , FIG. 4 is a circuit diagram showing details of the power supply interface circuit shown in FIG. 1, FIG. 5 is a circuit diagram showing details of the data transfer interface circuit using radio waves, and FIG.
The figure is a circuit diagram showing details of a data transfer interface circuit using magnetic coupling. 1... Optical card, 2,1)... Power supply coil, 3.
13... Photodetector, 4.12... Light emitting element, 5... Optical recording medium, 6... Power receiving circuit, ? , 16
．． 20... Receiving circuit, 8.15.19-... Transmitting circuit, 17.18... Tuning coil, 21a. 21b... Electromagnetic coil, 22.28... PM modulation circuit, 23° 24, 26.29... Amplifier, 25.27
...Phase detector. 1st Calendar 2E Figures 3 to 4

Claims (5)

[Claims] (1) An optical card equipped with an integrated circuit such as a semiconductor memory or the like together with an optical recording medium, characterized by being provided with a transmission means for exchanging data and supplying power to and from an external device to and from the integrated circuit without contact. An interface for an optical card equipped with an IC. (2) An interface for an IC-equipped optical card according to claim (1), wherein the transmission means for sending and receiving the data is based on optical communication. (3) The transmission means for power supply is configured to induce an AC voltage applied to a power transmission coil on the external device side into a power reception coil provided on the optical card, and rectify it to obtain a DC voltage. An interface for an IC-equipped optical card according to claim (1), characterized in that: (4) An interface for an IC-equipped optical card according to claim (1), wherein the transmission means for transmitting and receiving data modulates the data and transmits it by radio waves. (5) The transmission means for sending and receiving data is configured such that an electromagnetic coil for both sending and receiving is provided on the optical card, and data is transmitted between the electromagnetic coil provided on the external device and the electromagnetic coil using magnetic lines of force as a transmission medium. An interface for an IC-equipped optical card according to claim (1), characterized in that: