JP2000322544A - Portable electronic device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a composite IC card which can prevent a case where both contact and noncontact methods perform simultaneously their individual data communications in a single card, can accordingly prevent the malfunction that is caused by the above case and can attain the data communication with higher safety. SOLUTION: This composite IC card can transmit and receive the data to and from an external device by a noncontact method using a radio antenna and a contact method using the contact terminals. A selection circuit 12 of the IC card controls a changeover switch circuit 9 to usually connect a power generation circuit 5, a demodulation/modulation circuit 7 and a clock generation circuit 8 to a CPU 11 and to allow only a communication action of the noncontact method. Under such conditions, the switching of the circuit 9 is controlled when the circuit 12 detects that the power voltage is supplied to a contact terminal 10a. Then the contact terminals 10a-10e are connected to the CPU 11 and only a communication action of the contact method is allowed.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to a non-contact type using a wireless antenna and a contact type using a contact terminal.
The present invention relates to a portable electronic device that can transmit and receive data to and from a card reader / writer as an external device by a system, so-called a composite IC card.

[0002]

2. Description of the Related Art In recent years, IC cards equipped with LSIs, which have attracted attention, are mainly classified into a contact type in which data communication with an external device is performed through a contact terminal and a non-contact type in which data communication is performed through a wireless antenna. Separated.

[0003] A composite IC card, which is a mixed-type IC card of a contact type and a non-contact type, is an IC having both a contact terminal for performing data communication in a contact type and an antenna for performing data communication in a non-contact type. Card.

[0004] As such a complex IC card, for example, the one disclosed in Japanese Patent Application Laid-Open No. Sho 60-179891 is known. Here, a hybrid IC card that allows reading and writing of a memory during contact-type data communication and only allows reading of a memory during non-contact data communication is presented.

Further, as a complex IC card, for example,
Japanese Patent Application Laid-Open No. 9-326021 is known. Here, a rechargeable battery is provided inside the card, and during contact-type data communication, the battery is charged with a power supply from an external device. A hybrid IC card driven by the voltage of a charged battery when the value is less than the value is presented.

Further, as a composite IC card, for example, a card as disclosed in Japanese Patent Application No. 10-75692 has been considered. Here, a switching circuit is provided inside the card, it is determined whether the card is activated by the contact type or the non-contact type, and the executable commands are switched to prevent the malfunction at the time of each data communication. A form IC card is presented.

[0007]

However, Japanese Patent Application Laid-Open Nos. 60-17991 and 9-32602 mentioned above disclose the above-mentioned problems.
In the composite IC card as disclosed in Japanese Patent Laid-Open No. 1-2003, data communication with an external device is performed in a non-contact manner via an antenna while being performed in a contact manner via a contact terminal, or When data communication with an external device is performed in a non-contact manner via an antenna and when the data communication is performed in a contact manner via a contact terminal, no measure is taken to prevent malfunction.

In the case of a complex IC card as disclosed in Japanese Patent Application No. 10-75692, as a countermeasure, it is determined which of a contact type and a non-contact type is activated, and switching is performed to switch executable commands. A circuit is provided. However, since it detects both contact and non-contact states,
There is a problem that the number of constituent circuits increases. In addition, when power is supplied simultaneously by both contact and non-contact methods, a malfunction may occur.

Therefore, the present invention eliminates the simultaneous data communication operation of the contact type and the non-contact type in one device, and prevents the occurrence of malfunctions caused by this. An object of the present invention is to provide a portable electronic device capable of performing a data communication operation with excellent security.

[0010]

SUMMARY OF THE INVENTION A portable electronic device according to the present invention generates an antenna for wirelessly communicating with an external device and a power source used in the portable electronic device from radio waves received by the antenna. A power supply generating unit, a non-contact communication unit that operates by being supplied with power generated by the power generation unit, and performs non-contact data transmission / reception with an external device via the antenna; A contact terminal for receiving a power supply used in the portable electronic device from the external device, and transmitting and receiving data to and from the external device, by contacting the power supply unit with the contact terminal. Is supplied and operates, and permits the operation of the contact-type communication means for transmitting and receiving data to and from the external device through the contact terminal by contact, and usually the operation of the non-contact communication means. And control means for permitting operation of the contact-type communication means and prohibiting operation of the non-contact communication means when detecting that power from the contact terminal is received. .

Further, the portable electronic device of the present invention includes an antenna for wirelessly communicating with an external device, and a power supply generating means for generating a power supply used in the portable electronic device from a radio wave received by the antenna. A non-contact type communication unit that operates by being supplied with power generated by the power generation unit and performs non-contact data transmission / reception with an external device via the antenna; and a contact unit of the external device. By contacting, a power supply and a clock pulse used in the portable electronic device are received from an external device, and a contact terminal for transmitting and receiving data to and from the external device, a power supply received at the contact terminal, A contact-type communication unit that operates upon supply of a clock pulse and transmits and receives data to and from an external device via the contact terminal by contact; When the operation of the contact-type communication means is permitted, and when it is detected that a clock pulse is received from the contact terminal, the operation of the contact-type communication means is permitted, and the operation of the non-contact communication means is permitted. And control means for prohibiting the operation.

Further, the portable electronic device of the present invention includes an antenna for wirelessly communicating with an external device, and a power supply generating means for generating a power supply used in the portable electronic device from a radio wave received by the antenna. A non-contact type communication unit that operates by being supplied with power generated by the power generation unit and performs non-contact data transmission / reception with an external device via the antenna; and a contact unit of the external device. By contacting, a power supply and a clock pulse used in the portable electronic device are received from an external device, and a contact terminal for transmitting and receiving data to and from the external device, a power supply received at the contact terminal, A contact-type communication unit that operates upon supply of a clock pulse and transmits and receives data to and from an external device via the contact terminal by contact; When the operation of the contact-type communication means is permitted, it is detected that power from the contact terminal is received, and when it is detected that a clock pulse is received from the contact terminal, the contact-type communication means is detected. And a control means for permitting the above operation and prohibiting the operation of the non-contact type communication means.

Further, in the portable electronic device according to the present invention, the control means first detects that power has been received from the contact terminal, and then only when detecting that a clock pulse has been received from the contact terminal. The operation of the contact-type communication means is permitted, and the operation of the non-contact communication means is prohibited.

According to the present invention, by detecting an input signal (power supply voltage or clock pulse) from a contact terminal and switching between contact-type and non-contact type communication means, a contact-type or a non-contact-type communication means is provided in one device. -Each non-contact type does not perform individual data communication operations at the same time, thereby preventing the occurrence of erroneous operations caused by this, and enabling more secure data communication operations.

Further, according to the present invention, the state of both types is detected by using one signal (power supply voltage or clock pulse) from the contact terminal as a signal for detecting the state. Therefore, the load of the signal detection operation is reduced, and the number of constituent circuits is reduced. In addition, by using only one signal from the contact terminal to detect the state, the safety of each data communication operation is the same as that of the related art.

Further, according to the present invention, two signals (power supply voltage and clock pulse) from the contact terminal are used as signals for detecting the state, so that the conventional state detecting both types of states. Rather, contact-type data communication can be performed more reliably. Further, by using two signals for detecting the state from the contact terminal, the safety of each data communication operation is the same as that of the conventional one.

[0017]

Embodiments of the present invention will be described below with reference to the drawings.

First, a first embodiment will be described.

FIG. 1 is a composite IC according to a first embodiment.
2 schematically shows a configuration of a card. Basic functions of the complex IC card according to the present embodiment include, for example, storing data transmitted from an external device in an internal memory according to a command from an external device (for example, a card reader / writer), The data stored in the internal memory is read out and transmitted to an external device. These are performed by a contact type or a non-contact type.

In the case of the contact type, power supply and processing instructions are received from an external device via contact terminals. On the other hand, in the case of the non-contact type, there is no contact with the external device, the radio wave is received from the antenna, the power is generated, and the processing instruction is demodulated.
Operate.

In FIG. 1, an antenna 1 is used for wireless (non-contact) communication with an external device (not shown), and is composed of a loop-shaped coil. A tuning capacitor 2 is connected in parallel between both ends of the antenna 1, and these constitute a parallel tuning circuit.

A full-wave rectifier circuit 3 is provided between both ends of the antenna 1.
Is connected. The DC output terminal of the full-wave rectifier circuit 3
The shunt regulator circuit 4 and the power generation circuit 5 are connected. The shunt regulator circuit 4 stabilizes the output voltage of the full-wave rectifier circuit 3. The power supply generation circuit 5 generates a DC voltage for a power supply used in the card from the output voltage of the full-wave rectification circuit 3, and the DC voltage generated here is supplied to each circuit as an operation power supply.

One end of the antenna 1 is connected to the output terminal of the transmitting circuit 6. The input terminal of the transmission circuit 6 is connected to the modulation output terminal of the demodulation / modulation circuit 7. The transmission circuit 6
The antenna 1 based on the modulation data from the demodulation / modulation circuit 7
, The data is transmitted from the antenna 1.

The demodulation input terminal of the demodulation / modulation circuit 7 is connected to the other end of the antenna 1. The demodulation / modulation circuit 7 modulates transmission data and sends it to the transmission circuit 6,
And demodulates the received data from the CPU 11 and sends it to the CPU 11 described later.

The other end of the antenna 1 is connected to a clock generation circuit 8
It is connected to the. The clock generation circuit 8 includes the antenna 1
Is used to generate clock pulses used in the demodulation / modulation circuit 7 and the CPU 11 described later.

The output terminal of the power generation circuit 5, the demodulation output terminal and the modulation input terminal of the demodulation / modulation circuit 7, and the clock generation circuit 8
Are connected to the changeover switch circuit 9, respectively. The changeover switch circuit 9 will be described later in detail,
Switching of contact type or non-contact type is performed.

Contact terminals 10a, 10b, 10c, 10
d and 10e are for performing contact-type communication with an external device by contacting with a contact portion of the external device (not shown), and are provided on the surface of a card body (not shown).
When the composite IC card is inserted into an external device, it comes into contact with a contact portion of the external device.

Here, the contact terminal 10a is a terminal to which operating power is supplied, the contact terminal 10b is a terminal to which a reset (RST) signal is supplied, the contact terminal 10c is a terminal to which a clock pulse (CLK) is supplied, and the contact terminal. Reference numeral 10d denotes a terminal to which a ground potential (GND) is applied, and contact terminal 10e denotes a terminal through which data is input / output (I / O).

Contact terminals 10a, 10b, 10c, 10
d and 10e are connected to the changeover switch circuit 9, respectively. The output of the changeover switch circuit 9 is sent to a CPU (Central Processing Unit) 11 as control means for controlling the entire control.

The contact terminal 10a is connected to the selection circuit 12. The control signal from the CPU 11 is supplied to the selection circuit 12. The selection circuit 12 includes a contact terminal 10a
Of the switch circuit 9 is controlled based on the detection result or a control signal from the CPU 11. That is, normally, the power supply generation circuit 5, the demodulation / modulation circuit 7, and the clock generation circuit 8 are connected to the CPU 11, and the contact terminals 10a to 10a are connected.
The changeover switch circuit 9 is controlled so as to disconnect 10e from the CPU 11, permitting only the non-contact type communication operation and prohibiting the contact type communication operation. In this state, contact terminal 1
When it is detected that the power supply voltage has been supplied to the contact terminal 0a, the switch terminal 9 is switched to control the contact terminal 1a.
0a to 10e are connected to the CPU 11 to allow only the contact-type communication operation, and the power supply generation circuit 5, the demodulation / modulation circuit 7, and the clock generation circuit 8 are separated from the CPU 11 to perform the non-contact communication operation. Is prohibited.

The CPU 11 has a ROM 13 for storing a control program for the CPU 11, a RAM 14 as a working memory, and an EEPROM for storing various data.
15. An encryption circuit 16 for encrypting data is connected to each other.

Each of the above parts (parts enclosed by broken lines)
It is composed of one (or a plurality) of IC chips and is embedded in the card body.

Next, the operation of the above configuration will be described with reference to the flowchart shown in FIG.

First, at normal time, inside the card, only data communication and power supply by a non-contact type, that is, only a non-contact type communication operation are permitted. That is, the selection circuit 12
Normally, the power supply generation circuit 5, the demodulation / modulation circuit 7, and the clock generation circuit 8 are connected to the CPU 11, and the changeover switch circuit 9 is controlled to disconnect the contact terminals 10a to 10e from the CPU 11. Only the communication operation is permitted, and the contact-type communication operation is prohibited.

In this state, when the antenna 1 receives a radio wave transmitted from an external device, the received signal is rectified by the full-wave rectification circuit 3 and then sent to the power generation circuit 5, where the power supply voltage is generated. , Are supplied to each section as operating power. Further, the received signal is sent to a clock generation circuit 8 to generate a clock pulse, and the demodulation / modulation circuit 7 and the CPU
It is sent to 11.

The received signal is sent to the demodulation / modulation circuit 7 where the received data is demodulated, and the demodulated data is sent to the CPU 11. The CPU 11 performs a predetermined process according to the result of decoding by decoding the command in the received data.

That is, for example, if the decoded command is a data read command, the CPU 11
The data designated by the command is read out from 15 and sent to the demodulation / modulation circuit 7 as transmission data. The demodulation / modulation circuit 7 modulates the transmission data, sends it to the transmission circuit 6, radiates it as radio waves from the antenna 1, and transmits it to an external device.

Next, when the selection circuit 12 detects the power supply voltage from the contact terminal 10a in the non-contact type operation standby state, the contact terminals 10a to 10e are controlled by switching the changeover switch circuit 9. By connecting to the CPU 11, only the contact type communication operation is permitted, the power supply generation circuit 5, the demodulation / modulation circuit 7, and the clock generation circuit 8 are separated from the CPU 11 to prohibit the non-contact type communication operation.

That is, when the selection circuit 12 detects the power supply voltage from the contact terminal 9a and the changeover switch circuit 9 connects the contact terminals 10a to 10e to the CPU 11, the power supply voltage supplied to the contact terminal 10a and the contact terminal 10b The supplied reset signal, the clock pulse supplied to the contact terminal 10c, the ground potential supplied to the contact terminal 10d, and the transmission data supplied to the contact terminal 10e are CP, respectively.
Sent to U11. The power supply voltage supplied to the contact terminal 10a is supplied as operation power for each unit.

The CPU 11 performs a predetermined process according to the result of decoding by decoding the command in the received data. That is, for example, if the decoded command is a data write command, the CPU 11 writes the write data received together with the command at the address specified by the command in the EEPROM 15.

When the contact-type communication operation is completed, the CPU 11 sends the changeover switch circuit 9 to the selection circuit 12.
Send a control signal. Selection circuit 1 receiving this control signal
2 switches the switching switch circuit 9 to disconnect the contact terminals 10a to 10e from the CPU 11 again, and connects the power supply generation circuit 5, the demodulation / modulation circuit 7, and the clock generation circuit 8 to the CPU 11, Only the non-contact type communication operation is permitted, and the contact type communication operation is prohibited.

In the non-contact type operation standby state, when both contact type and non-contact type data communication and power supply are performed simultaneously, for example, when the contact type communication operation is performed, the non-contact type In the case where the communication operation of the contact circuit 10 is started, or when the communication operation of the contact method is started while the communication operation of the non-contact method is performed, the selection circuit 12 detects only the power supply voltage of the contact terminal 10a. , The communication operation by the contact type is preferentially permitted, and the communication operation by the non-contact type is prohibited.

Next, a second embodiment will be described.

FIG. 3 shows a composite IC according to the second embodiment.
2 schematically shows a configuration of a card. In the first embodiment shown in FIG. 1, the detected signal of the selection circuit 12 is the power supply voltage from the contact terminal 10a, whereas in the second embodiment, the detected signal of the selection circuit 12 is Contact terminal 1
The clock pulse from 0c is used. That is, a clock detection circuit 17 for detecting whether or not a clock pulse is supplied to the contact terminal 10c is provided, and the selection circuit 12 switches and controls the changeover switch circuit 9 based on the detection result.

That is, normally, the power supply generation circuit 5
The modulation circuit 7 and the clock generation circuit 8 are connected to the CPU 11
And the contact terminals 10a to 10e are connected to the CPU.
Control the changeover switch circuit 9 so as to disconnect it from
Only non-contact type communication operation is permitted, and contact type communication operation is prohibited. In this state, when the clock detection circuit 17 detects that the clock pulse is supplied to the contact terminal 10c, the switching terminals 9a to 10e are connected to the CPU 11 by controlling the switching of the changeover switch circuit 9, and
While permitting only the contact type communication operation, the power generation circuit 5, the demodulation / modulation circuit 7, and the clock generation circuit 8
Is separated from the CPU 11 to prohibit a non-contact type communication operation.

Since the basic operation is the same as that of FIG. 1, further detailed description will be omitted. FIG. 4 shows an operation flowchart of the composite IC card of FIG.

Next, a third embodiment will be described.

FIG. 5 shows a composite IC according to the third embodiment.
2 schematically shows a configuration of a card. The third embodiment is a combination of the first and second embodiments described above. That is, the power supply voltage and the clock pulse from the two contact terminals 10a and 10c are detected, and executable data communication and power supply switching are performed.

In this case, the basic operation is as shown in FIG.
3 and FIG. 3, but in the non-contact operation standby state, the selection circuit 12 first detects the power supply voltage from the contact terminal 10a, and then the clock detection circuit 17 detects the clock pulse from the contact terminal 10c. If detected, select circuit 1
2 connects the contact terminals 10a to 10e to the CPU 11 by switching and controlling the changeover switch circuit 9,
While permitting only the contact type communication operation, the power generation circuit 5, the demodulation / modulation circuit 7, and the clock generation circuit 8
Is separated from the CPU 11 to prohibit a non-contact type communication operation.

The reason why the power supply voltage is first detected is to operate the clock detection circuit and the like in the CPU 11 by the power supply voltage. FIG. 6 shows an operation flowchart of the complex IC card of FIG.

As described above, according to the above-described embodiment, one card is detected by detecting the power supply voltage or clock pulse from the contact terminal and switching the contact type or non-contact type communication means. Within each of the contact and non-contact types, individual data communication operations are not performed at the same time, which prevents malfunctions caused by this and enables more secure data communication operations .

Further, by setting the signal for detecting the state to one of the power supply voltage from the contact terminal or one of the clock pulses, the load of the signal detecting operation is reduced as compared with the conventional one in which both types of states are detected. This reduces the number of constituent circuits. Further, by using only one signal for detecting the state from the contact terminal, the safety of each data communication operation is not different from that of the conventional one.

Further, by using two signals, a power supply voltage from a contact terminal and a clock pulse, as signals for detecting a state, a contact-type data communication can be performed as compared with the conventional one in which both types of states are detected. Can be performed more reliably. Further, by using two signals from the contact terminals for detecting the state, the safety of each data communication operation is not different from the conventional one.

[0054]

As described above in detail, according to the present invention, 1
Contact and non-contact types do not perform individual data communication operations simultaneously in one device, preventing malfunctions caused by this and enabling more secure data communication operations Portable electronic device can be provided.

[Brief description of the drawings]

FIG. 1 is a block diagram schematically showing a configuration of a composite IC card according to a first embodiment of the present invention.

FIG. 2 is a flowchart illustrating an operation of the complex IC card according to the first embodiment.

FIG. 3 is a block diagram schematically showing a configuration of a composite IC card according to a second embodiment of the present invention.

FIG. 4 is a flowchart illustrating an operation of the complex IC card according to the second embodiment.

FIG. 5 is a block diagram schematically showing a configuration of a composite IC card according to a third embodiment of the present invention.

FIG. 6 is a flowchart illustrating an operation of the complex IC card according to the third embodiment.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 ... Antenna 2 ... Tuning capacitor 3 ... Full-wave rectifier circuit 5 ... Power generation circuit 6 ... Transmission circuit 7 ... Demodulation / modulation circuit 8 ... Clock generation circuit 9 ... Changeover switch circuit 10a-10e ... Contact terminal 11 ... CPU 12 ... Selection circuit 13 ... ROM 14 ... RAM 15 ... EEPROM 17 ... Clock detection circuit

Claims (6)

[Claims] An antenna for wirelessly communicating with an external device, power generation means for generating power used in the portable electronic device from radio waves received by the antenna, and power generation means generated by the power generation means A non-contact communication unit that operates when supplied with power and transmits and receives data to and from an external device through the antenna in a non-contact manner; A power supply used in the device is received from an external device, and a contact terminal for transmitting and receiving data to and from the external device, and the power received at the contact terminal is supplied and operated, and the operation is performed through the contact terminal. Contact-type communication means for transmitting and receiving data by contact with an external device, and usually permits the operation of the non-contact type communication means,
Upon detecting that power has been received from the contact terminal,
Control means for permitting operation of the contact-type communication means and prohibiting operation of the non-contact communication means. 2. An antenna for wirelessly communicating with an external device, power generation means for generating power used in the portable electronic device from radio waves received by the antenna, and power generation means generated by the power generation means. A non-contact communication unit that operates when supplied with power and transmits and receives data to and from an external device through the antenna in a non-contact manner; A power terminal and a clock pulse used in the device are received from an external device, and a contact terminal for transmitting and receiving data to and from the external device, and the power and clock pulse received at the contact terminal are supplied and operated. A contact-type communication means for transmitting and receiving data to and from an external device via the contact terminal by contact, and normally permitting operation of the non-contact communication means Have been,
When detecting that a clock pulse has been received from the contact terminal, control means for permitting operation of the contact-type communication means and prohibiting operation of the non-contact communication means is provided. And a portable electronic device. 3. An antenna for wirelessly communicating with an external device, power generation means for generating power used in the portable electronic device from radio waves received by the antenna, and power generation means generated by the power generation means. A non-contact communication unit that operates when supplied with power and transmits and receives data to and from an external device through the antenna in a non-contact manner; A power terminal and a clock pulse used in the device are received from an external device, and a contact terminal for transmitting and receiving data to and from the external device, and the power and clock pulse received at the contact terminal are supplied and operated. A contact-type communication means for transmitting and receiving data to and from an external device via the contact terminal by contact, and normally permitting operation of the non-contact communication means Have been,
When detecting that power from the contact terminal has been received, and detecting that a clock pulse has been received from the contact terminal, the operation of the contact-type communication means is permitted, and the non-contact communication is performed. A portable electronic device, comprising: control means for inhibiting operation of the means. 4. When the control unit detects that power has been received from the contact terminal while data is being transmitted to and received from the external device by the non-contact communication unit, 2. The portable electronic device according to claim 1, wherein an operation of the contact-type communication unit is permitted, and a communication operation by the non-contact-type communication unit is prohibited. 5. The control means detects first that power from the contact terminal has been received, and then only when it detects that a clock pulse has been received from the contact terminal.
4. The portable electronic device according to claim 3, wherein the operation of the contact-type communication unit is permitted, and the operation of the non-contact-type communication unit is prohibited. 6. The control unit, when the transmission and reception of data with the external device by the contact-type communication unit is completed,
4. The portable device according to claim 1, wherein an operation of the non-contact type communication unit is permitted, an operation of the contact type communication unit is prohibited, and a standby state is set. Electronic devices.