JP2003036427A - Semiconductor integrated circuit device, portable terminal device and settling method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To seamlessly perform connection switching of a power source obtained by rectifying a carrier wave and an external power source. SOLUTION: This semiconductor integrated-circuit device having a non- contact card function and a non-contact reader/writer function is provided with a rectifier 131 for rectifying a received carrier wave, a serial regulator 132 for obtaining a predetermined voltage from an output voltage of the rectifier 131, and a power-supply control circuit 138 for tuning on/off the voltage from a battery 160. In a case where the output voltage of the battery 160 is equal to or higher than a predetermined voltage, the power=supply control circuit 138 selects the voltage of the battery 160 as power required for operation of an IC 300 when a reader/writer mode signal or a card mode signal is received. On the other hand, when the output voltage of the battery 160 is lower than the predetermined voltage, the power-supply control circuit 138 selects the output voltage from the rectifier 131 as power required for operation of the IC 300. The present invention can be applied to a portable terminal, such as a portable telephone set.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a semiconductor integrated circuit device, a mobile terminal device, and a settlement method, and more particularly, to a semiconductor integrated device equipped with an analog front end for a data carrier and / or an information processing device for an external data carrier. The present invention relates to a circuit device, a mobile terminal device equipped with the semiconductor integrated circuit device, and a settlement method using the mobile terminal device.

[0002]

2. Description of the Related Art A contactless IC card, for example, which has been introduced into a railway ticket gate system and used when passing through a ticket gate, has been put into practical use. FIG. 10 shows a contactless IC card,
FIG. 3 is a diagram showing a schematic configuration of a reader / writer device for reading / writing the non-contact IC card. In FIG. 10, 200 is a reader / writer (R / W) device, 300
Is a contactless IC card. 201 is a modulator / demodulator, 202 is
CPU, 203 is an oscillator, and 204 is an antenna. Thirty
1 is an antenna, 310 is a rectifier, 312 is a diode,
313 is a capacitor, 320 is a modulator, 322 is an impedance device, 323 is a FET diode, 330 is a high pass filter (HPF), 331 is a capacitor, 33
2 is a resistor, 340 is a regulator, 350 is a demodulator, 3
Reference numeral 60 is a sequencer and 370 is a memory.

The R / W device 200 and the IC card 300 shown in FIG. 10 constitute a non-contact IC card system for mutually transmitting and receiving data via each antenna. In such a non-contact IC card system, the non-contact IC card 300 rectifies a carrier wave modulated by the transmission data from the R / W device 200 to generate a DC voltage, which is used as an internal CPU or memory. The power is supplied to the circuit. Specifically, the voltage rectified by the rectifier 310 is adjusted to a predetermined voltage by the regulator 340 and supplied to the sequencer 360. On the other hand, the signal received by the antenna 301 is demodulated by the demodulator 350, supplied to the sequencer 360, and subjected to predetermined processing. The processed data is recorded in the memory 370.

When responding to the R / W device 200, the sequencer 3 in the non-contact IC card 300 is used.
The data processed by 60 is modulated by the modulator 320 and transmitted from the antenna 301. The signal received by the antenna 204 of the R / W device 200 is demodulated by the modulator / demodulator 201 and processed by the CPU 202.

In such a non-contact IC card system, the IC chip used for the non-contact IC card is integrated into one chip by a MOS process, a carrier wave from an external reader / writer is rectified to generate a DC voltage, It was used as a power source for circuits such as the internal CPU and memory.

[0006]

On the other hand, there has been proposed a mobile communication device having a so-called IC card function such as a data carrying and processing function by mounting the integrated circuit on the mobile communication device. Such a realization method was not revealed.

The present invention has been made in view of the above problems, and in a portable terminal device having an IC card function, by seamlessly switching between a power source obtained by rectifying a carrier wave and an external power source. , A semiconductor integrated circuit mounted on a mobile terminal device and equipped with analog front ends for both an IC card and an information processing device such as a reader / writer.

[0008]

A semiconductor integrated circuit device according to the present invention comprises a rectifying means for rectifying a received carrier wave, a generating means for generating a first power supply voltage based on an output from the rectifying means, and a generating means. The selection means includes a selection means for selecting one of the first power supply voltage generated by the means and the supplied second power supply voltage as a power supply voltage required for the operation, and the selection means has a predetermined second power supply voltage. When it is less than or equal to the threshold value, the first power source voltage is selected as the power source voltage required for operation, and when the second power source voltage is equal to or higher than a predetermined threshold value and it is instructed to operate with a predetermined function, the operation is started. A feature is that the second power supply voltage is selected as the required power supply voltage.

When the second power supply voltage is equal to or higher than a predetermined threshold value, the selecting means is instructed to operate by a data carrying and processing function for communicating with an external information processing device, or externally. When instructed to operate by the function of carrying data and communicating with the processing medium,
The second power supply voltage can be selected as the power supply voltage required for operation.

It is possible to configure a functional unit that implements a data carrying and processing function and a functional unit that implements a function of communicating with an external data carrying and processing medium by one chip.

The switching of the switches is controlled between the connection point of the rectifying means and the generating means and the ground point in accordance with a signal instructing to operate by the function of communicating with an external data carrying and processing medium. The control means further includes a control means, which turns off the switch when a signal is supplied, and the power supply voltage required by the selection means for operation is the second.
It is possible to prevent inflow of leakage current by the generating means, which occurs when the power supply voltage is selected.

Based on the carrier wave, a clock extracting means for extracting the first clock, a clock generating means for generating the second clock, a first clock extracted by the clock extracting means, and a clock generating means. And a clock selecting means for selecting one of the selected second clocks as a clock serving as a reference for the operation, the clock selecting means serving as the reference for the operation when the first clock is extracted by the clock extracting means. It is possible to select the first clock as the clock to be operated and to select the second clock as the clock to be the reference of the operation when the first clock is not extracted by the clock extracting means.

In the portable terminal device of the present invention, the rectifying means for rectifying the received carrier wave, the generating means for generating the first power supply voltage based on the output from the rectifying means, and the first for generating by the generating means. Of the second power source voltage and the second power source voltage to be supplied are selected as the power source voltage required for the operation, and the selecting means operates when the second power source voltage is equal to or lower than a predetermined threshold value. When the first power supply voltage is selected as the required power supply voltage, the second power supply voltage is equal to or higher than a predetermined threshold, and an instruction to operate with a predetermined function is issued, the second power supply voltage is used as the power supply voltage required for the operation. A semiconductor integrated circuit device for selecting a power supply voltage is provided inside.

The settlement method of the present invention comprises a rectifying means for rectifying a received carrier wave for settlement caused by a predetermined transaction.
Based on the output from the rectifying means, one of the generating means for generating the first power supply voltage, the first power supply voltage generated by the generating means, and the supplied second power supply voltage is the power supply voltage required for the operation. And a communication step for communicating with the mobile terminal device, which is a settlement method performed between the mobile terminal device and a selection means for selecting as a payment method and a storage means for storing amount information as a consideration for a predetermined transaction. And a settlement step of performing settlement based on the amount information read by the processing of the reading step, and a reading step of reading the amount information stored by the mobile terminal device by the processing of the communication step.

In the semiconductor integrated circuit device of the present invention and the semiconductor integrated circuit device provided in the mobile terminal device,
The received carrier wave is rectified, a first power supply voltage is generated based on the output, and one of the generated first power supply voltage and the supplied second power supply voltage is a power supply voltage required for operation. Is selected as. When the second power supply voltage is equal to or lower than a predetermined threshold value, the first power supply voltage is selected as a power supply voltage required for operation, the second power supply voltage is equal to or higher than the predetermined threshold value, and the operation is performed by a predetermined function. Is instructed, the second power supply voltage is selected as the power supply voltage required for the operation.

In the settlement method of the present invention, the amount information stored in the portable terminal device is communicated with the portable terminal device, and the settlement is performed based on the read amount information.

[0017]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiment 1. FIG. 1 is a schematic diagram illustrating a ticket inspection system using the mobile phone according to the first embodiment of the present invention as a contactless card. In FIG.
102 is a mobile phone having a card operation function, 104 is a ticket gate installed at a station, etc., 106 is a reader / writer device having a read / write function installed in the ticket gate 104, and 108 is a closed ticket gate. A plate 110 is a ticket passing plate in an open state.

Next, the ticket gate system of FIG. 1 will be briefly described. The user carries the mobile phone 102 and the ticket gate 1
It approaches 04. In the reader / writer device 106 installed in the ticket gate 104, the mobile phone 102 of the user is the ticket gate 1
When the approaching 04 is detected, communication is performed with the mobile phone 102, and mutual authentication with the mobile phone 102 (for example, payment based on the amount information stored in the mobile phone 102) is performed. Then, the ticket passing plate 108 is driven to open the ticket passing plate 108 as indicated by 110. This allows the user to pass through the ticket gate 104.

FIG. 2 is a schematic diagram illustrating a settlement system using the mobile phone according to the first embodiment of the present invention as a read / write device. In FIG. 2, 102 is a mobile phone having a read / write function, 120 is a contactless IC card, 121 is a base station antenna, 122 is a mobile communication network, 123 is a control computer provided in a center or the like, and 124 is for control. It is a data memory connected to the computer 123.

Next, the read / write operation performed by the mobile phone 102 with the non-contact IC card 120 in the settlement system of FIG. 2 will be briefly described. For example, when the number of boarding points recorded in the non-contact IC card 120 has decreased, the mobile phone 102 is
The information of the points recorded in 20 is read to grasp the shortage. The mobile phone 102 is a contactless IC card 12
If the points recorded in 0 are insufficient, the control computer 123 is accessed through the base station antenna 121 and the mobile communication network 122 to acquire points, and the acquired points are acquired by the contactless IC card 120. To write to using the read / write function.

Next, the configuration of the portable telephone 102 according to the first embodiment of the present invention having the above read / write function will be described. FIG. 3 shows an IC provided inside a mobile phone 102 to which the present invention having a read / write function is applied.
It is a figure which shows the example of an internal structure. In FIG. 3, IC30
0 is a card function unit 400, a read / write function unit 50
0 and a control unit 600.

In the card function unit 400, the antenna 1
The carrier wave received by 30 is rectified by the rectifier 131,
Power supply control circuit 13 via series regulator 133
8 is output. The power supply control circuit 138 controls the voltage from the series regulator 133 and supplies the power supply voltage (V _DD ) used in the entire IC 300 to each unit. here,
The series regulator 133 is a device that keeps the output voltage substantially constant regardless of the input voltage. That is, the power supply control circuit 138 performs the above-described operation by increasing the internal impedance when the input voltage is high and decreasing the internal impedance when the input voltage is low. The voltage detector 140 uses the power supply control circuit 13
The voltage of the external power supply (battery) connected to 8 is monitored,
When the voltage of the external power supply falls below a predetermined voltage, a signal for prohibiting the use of the external power supply is output to the power supply control circuit 138. The received signal from the external reader / writer is a rectifier 131
The signal is input to the receiver 139 via the converter, converted into a baseband signal inside the receiver 139, and converted into a signal processing unit (SP
U) It is passed to 144 and processed. The transmission signal to the external reader / writer is passed from the SPU 144 to the rectifier 131, the value of the load connected to the antenna 130 is changed according to the transmission signal inside the rectifier 131, and the carrier wave generated by the external reader / writer is transmitted. Amplitude modulation is performed on.

In the carrier detector 134, the antenna 1
It is determined whether the carrier wave is included in the radio wave received at 30. When the carrier wave detector 134 determines that the carrier wave is included, the carrier wave detector 134 outputs the carrier wave detection signal VR to the power supply control circuit 138. The clock extractor 135 extracts a clock based on the radio wave input from the antenna 130 and supplies the extracted clock to the clock selector 136. Clock oscillator 137
Is a crystal oscillator provided outside the IC chip,
Frequency used in IC300 (eg 13.56MH
The clock z) is generated and supplied to the clock selector 136. The clock selector 136 is a clock extractor 135.
Either the clock supplied from the clock generator or the clock supplied from the clock oscillator 137 is selected, and the selected clock is supplied to each unit of the IC 300. The entire operation of the card function unit 400 is controlled by the CPU 145 of the control unit 600 described later.

The read / write function unit 500 includes a transmission amplifier 150, a reception signal detector 153, and a reception amplifier 1.
It is composed of 54. The read / write function unit 500 is
It has a transmission / reception function, and at the time of transmission, the transmission signal supplied from the SPU 144 is amplified by the transmission amplifier 150 and transmitted from the antenna 151. On the other hand, at the time of reception, the signal received by the antenna 152 is the received signal detector 15
3 is detected, amplified by the reception amplifier 154, SPU1
The signal is processed by the SPU 144.

The control unit 600 includes a central control unit (CPU) 1
45, signal processing unit (SPU) 144, encryption (DES)
Engine 146, detector (CRC) that detects bit errors
147, primary memory (RAM) 141, read only memory (ROM) 142, and EEPROM 14 for recording data
3. UART circuit 14 for asynchronous serial communication with the outside
8 and an I ² C interface 149 for communicating with the outside.

In the present invention, since the card function section 400 and the read / write function section 500 are provided as described above, the switching of the power supplies is controlled so that the optimum power is supplied to these parts. . Further, in a mobile phone, the antenna structure used in a normal IC card cannot be used as it is, and it is necessary to incorporate an antenna suitable for the mobile phone. Even in this case, the IC card unit (IC300 It is possible to supply sufficient electric power by supplying power from a battery.

The IC 300 has an external card mode in which it communicates with an external read / write device via the card function unit 400, and an external non-contact via the read / write function unit 500.
It has three operation modes: a reader / writer mode for communicating with an IC card and an internal card mode for processing an internal card placed inside.

FIG. 4 is a diagram showing a flow chart for selecting the above-mentioned three operation modes. In FIG. 4, the CPU
The step 145 makes a mode decision in step S1. CPU14
If the external card mode is determined to be the external card mode in step S1, the external card 5 executes the external card mode in which card processing is performed with the external reader / writer device via the card function unit 400 in step S5. When the CPU 145 determines in step S1 that the card is in the internal card mode, the CPU 145 interprets the command in step S2, and in the internal card mode, processes the card placed inside. On the other hand, the CPU 145, in step S2,
When it is determined that it is the R / W mode, the process proceeds to step S3, and the reader / writer mode is executed with the external non-contact IC card via the read / write function unit 500.

Note that the antenna for the card and the antenna for the reader / writer, or the transmitting and receiving antennas for the reader / writer do not have to be separate, and one antenna may be used in common.

In the present invention, the output of the power supply control circuit 138 (power supply generated from the carrier wave) is supplied to the V _DD terminal. On the other hand, the power from the battery is similarly supplied to the V _DD terminal via the power control circuit 138. These two power supplies are P from a mobile phone (controller not shown).
Either is selected by a logical combination of the _ON signal and the signal VR from the carrier wave detector 134.

Switching of the power supply of the mobile phone configured as described above will be described below. FIG. 5 is a diagram showing in more detail the carrier wave rectifying circuit and the power supply control circuit of the mobile phone according to the first embodiment of the present invention. In FIG.
The carrier wave received by the antenna 130 is rectified by the rectifier 131 and supplied to the power supply terminal V _DD via the series regulator 133.

On the other hand, the output of the battery 160 is connected to the power supply terminal V _DD via the power supply control circuit 138. The power control circuit 138 includes a switch SWen16 between the input and the output.
2 and a switch SWcont164 are provided. The switch SWen 162 is turned on / off by the control voltage as shown in FIG. 6 by the power supply voltage V _BT of the battery 160. On the other hand, the switch SWcont164 is provided with P _ON supplied from the outside and VR supplied from the carrier wave detector 134.
The signal is turned on and off by the control logic shown in FIG.

FIG. 6 is a diagram showing a control logic for operating the switch SWen 162. As shown in FIG. 6, the switch SWen 162 outputs an enable signal en (a signal indicating “1”) from the power supply detector 140 (VDET 140) when the voltage V _{BT of the} battery 160 is equal to or higher than a predetermined value.
It is turned on by this signal. On the other hand, the battery 160
If the voltage V _BT of the power supply is less than a predetermined value, the power supply detector 140
(VDET140) does not output enable signal en,
The switch SWen 162 remains off.

FIG. 7 is a diagram showing a control logic for operating the switch SWcont 164. As shown in FIG. 7, the switch SWcont 164 is turned on when either the P _ON signal or the VR signal is high (“1”), and remains off otherwise. Here, the _PON signal is
This is a writer mode signal, and when the user instructs the mobile phone to perform a read / write operation, a high _PON signal is output from the mobile phone. On the other hand, the VR signal is
When the carrier wave detector 134 detects a carrier wave in the received radio wave, a high VR signal is output. That is,
The high VR signal means that the mobile phone (IC300)
Indicates that the mobile phone operates in the card mode, and that the _PON signal is high indicates that the mobile phone operates in the reader / writer mode. CPU145 recognizes whether these VR signals or by P _ON signal, the mobile phone is operating in either the reader-writer mode is operating in the card mode. In FIG. 7, when the _PON signal and the VR signal are both high, the control logic 163 exclusively selects one of the card mode and the reader / writer mode.
This exclusive selection can preferentially select the operation that goes high earlier in time. Of course, other methods may be used for exclusive selection.

The output of the switch SWcont 164 is connected to the output of the series regulator 133. Therefore, the switch SWen 162 and the switch SWcont 16
When both 4 are on, the voltage V from the battery 160
_BT is supplied as V _DD . As described above, the series regulator 133 is equivalently structured to control the internal impedance by the difference between the output voltage and a certain reference voltage, and the series regulator 133 generates the card (rectifier 131) from the card generated by the series regulator 133. When the battery voltage is higher than the rectified voltage, the internal impedance of the series regulator 133 becomes extremely large, which prevents the voltage of the battery 160 from flowing backward to the input side of the series regulator 133.

Even if some current flows backward from the battery 160 to the input side of the series regulator 133,
Since the diode inside the rectifier 131 is reverse biased and the impedance becomes high, the reverse current from the input side of the series regulator 133 to the rectifier 131 can be made very small. On the other hand, when either the switch SWen 162 or the switch SWcont 164 is turned off, the power from the battery 160 is not supplied as V _{DD and} only the rectified voltage of the carrier is supplied to the output of the series regulator 133, so that the power supply is switched. It can be done seamlessly without interruption. In addition, even when the distance between the external reader / writer device and the external reader / writer device becomes relatively large and the power supply voltage generated from the carrier wave cannot be sufficiently secured,
Communication can be performed by using the power source supplied from the battery 160. Therefore, the communicable distance can be increased.

The circuits of FIGS. 3 and 5 can be realized by a MOS process, and all the circuits in FIGS. 3 and 5 are MO of one chip.
Can be placed in SLSI.

Embodiment 2. FIG. 8 is a diagram showing a mobile phone having a card function and a reader / writer function according to the second embodiment of the present invention. FIG. 8 is a modified circuit of FIG. 5, and particularly, the power supply control circuit 170 and the protector 18
The difference from the first embodiment is that 0 is provided.

The VDET 140 monitors the output voltage of the battery 160, and when the output voltage (battery voltage V _BT ) is smaller than a predetermined value, outputs a V _B signal of "0" level to the AND circuit 171 of the power supply control circuit 170. Then, when the battery voltage V _BT is higher than a predetermined value, the V _B signal of “1” level is ANDed.
Output to the circuit 171.

The power supply control circuit 170 receives the V _B signal supplied from the VDET 140, the P _ON signal indicating that it operates in the reader / writer mode, and the carrier wave detector 134 when the carrier wave is detected in the received radio wave. The switch SW173 is controlled based on the signal VR supplied from the switch SW173.

FIG. 9 is a diagram showing the control logic of the switch SW173 by the power supply control circuit 170. In FIG. 9, the V _B signal corresponds to the output voltage of the VDET 140, and becomes “0” when the battery voltage V _BT is low, and becomes “1” when the battery voltage V _BT is high. According to FIG. 9, the switch SW173 is in the off state while the battery voltage V _BT is low (while it is below the predetermined value), and the battery voltage V _BT is high (when it is above the predetermined value), and, one of the P _oN signal and the VR signal is turned on when high. The card mode, reader / writer mode, and exclusive logic are the same as in the case of FIG. That is, when one of the P _ON signal and the VR signal is high, the switch SW173 is turned on.

The protector 180 is a circuit composed of a MOS circuit arranged on the IC chip. Protector 18
0 is the output of the rectifier 131 and the series regulator 13
It is connected between the connection point 3 and the ground, and is controlled by the reader / writer mode signal P _ON . Specifically, when the reader / writer mode signal P _ON is not applied (for example, when operating in the card mode), the resistance of the protector 180 is controlled to be extremely small (the internal switch is turned on). Then, the excessive voltage generated by the rectifier 131 based on the carrier wave is output to the ground.

On the other hand, when the reader / writer mode signal P _ON is applied, the resistance inside the protector 180 is made infinite (the internal switch is turned off), and the inside of the protector 180 of the leak current by the series regulator 133 is made. Supply to the resistor is prevented.

By thus providing the protector 180 and turning off the protector 180 in the reader / writer mode (when the reader / writer mode signal P _ON is applied), the protector 180 is normally operated (especially realized by CMOS). It is possible to prevent current loss due to the leak current of the series regulator 133 which occurs when

As a result, it is possible to provide a mobile phone which realizes low cost and high reliability of the product by making both the IC card and the reader / writer into one chip by the MOS process.

The above "IC card" and "card function" are
The medium is used for convenience to refer to the medium having data carrying and processing functions and the data carrying and processing functions, respectively, and does not refer to a card shape. In addition, in the above-described embodiment, the case where the semiconductor integrated circuit is built in the mobile phone is illustrated, but the fixed telephone connected by wire and the personal digital assistant (Personal Digital Assi
stants), clocks, computers, etc.
The present invention can be applied regardless of the presence or absence of a wireless communication function. The semiconductor integrated circuit may be incorporated in the portable terminal device in a detachable or non-detachable manner, or an IC card containing an IC or an external storage medium such as a memory card may be used as a portable telephone device. Alternatively, it may be detachably attached to a personal digital assistant, a computer, or the like.

[0047]

According to the present invention, a semiconductor integrated circuit capable of seamlessly switching between an external power supply and a carrier wave rectification power supply can be realized. Therefore, by mounting the semiconductor integrated circuit in various devices, it is possible to use for a card and a reader. A device equipped with both analog front ends for an information processing device such as a writer can be realized. It also has a memory for services compatible with the memory built in the semiconductor integrated circuit, and a wireless interface and UA for communication with external devices.
Two communication interfaces, the RT interface, can be used. As a result, the mobile terminal device equipped with the semiconductor integrated circuit according to the present invention operates as a remote IC card and also functions as a reader / reader for the remote IC card.
It also becomes possible to operate as a writer.

[Brief description of drawings]

FIG. 1 is a schematic diagram illustrating a ticket inspection system that uses a mobile phone according to a first embodiment of the present invention as a contactless card.

FIG. 2 is a schematic diagram illustrating a payment system that uses the mobile phone according to the first embodiment of the present invention as a read / write device.

FIG. 3 is a diagram showing a configuration of a mobile phone having a read / write function according to the first embodiment of the present invention.

FIG. 4 is a diagram showing a flowchart for selecting three operation modes of the mobile phone according to the first embodiment of the present invention.

FIG. 5 is a diagram showing a carrier wave rectifying circuit and a logic circuit of the mobile phone according to the first embodiment of the present invention.

FIG. 6 is a diagram illustrating a control logic of a switch SWen according to the first embodiment of the present invention.

FIG. 7 is a diagram illustrating a control logic of the switch SWcont according to the first embodiment of the present invention.

FIG. 8 is a diagram showing a carrier wave rectifying circuit and a logic circuit of a mobile phone according to a second embodiment of the present invention.

FIG. 9 is a diagram illustrating a control logic of a switch SW according to the second embodiment of the present invention.

FIG. 10 Conventional non-contact IC card and its non-contact IC
It is a figure which shows schematic structure of the reader / writer apparatus which reads / writes a card.

[Explanation of symbols]

102 ... mobile phone, 104 ... wicket, 106 ... reader / writer device, 108 ... wicket passing plate, 120 ... non-contact IC
Card, 121 ... Base station antenna, 122 ... Mobile communication network, 123 ... Control computer, 124 ... Data memory, 130 ... Antenna, 131 ... Rectifier, 1
33 ... Series regulator, 134 ... Carrier wave detector,
135 ... Clock extractor, 136 ... Clock selector, 1
37 ... Clock oscillator, 138 ... Power supply control circuit, 139
... receiver, 140 ... voltage detector, 141 ... RAM, 142
... ROM, 143 ... EEPROM, 144 ... SPU, 145 ... CPU,
146 ... DES engine, 147 ... CRC, 150 ... Transmission amplifier, 153 ... Reception signal detector, 154 ... Reception amplifier, 1
60 ... Battery, 162 ... SWen, 163 ... Control logic, 164 ... SWcont, 170 ... Power supply control circuit, 171
... AND circuit, 172 ... OR circuit, 180 ... Protector, 200 ... R / W device, 300 ... IC card, 400 ...
Card function unit, 500 ... Read / write function unit, 600
… Control unit

─────────────────────────────────────────────────── ─── Continuation of front page (51) Int.Cl. ⁷ Identification code FI theme code (reference) H04B 7/26 H04M 1/00 V H04M 1/00 1/725 G06K 19/00 J 1/725 H H04B 7 / 26 M R F term (reference) 5B035 AA06 BB09 CA12 CA23 5B058 CA22 KA02 KA04 YA20 5G003 BA01 DA16 DA18 EA06 GB08 GC05 5K027 AA11 BB01 GG02 HH26 MM03 5K067 AA21 BB04 BB34 DD11 DD51 FF02 OH

Claims (7)

[Claims] 1. Rectifying means for rectifying a received carrier wave, generating means for generating a first power supply voltage based on an output from the rectifying means, and the first power supply voltage generated by the generating means. When,
Selecting means for selecting one of the supplied second power supply voltage as a power supply voltage required for operation, wherein the selecting means has a power supply voltage required for operation when the second power supply voltage is equal to or lower than a predetermined threshold value. When the first power supply voltage is selected as, the second power supply voltage is equal to or higher than a predetermined threshold value, and it is instructed to operate by a predetermined function, the second power supply voltage is used as the power supply voltage required for the operation. A semiconductor integrated circuit device characterized by selecting a power supply voltage. 2. The selecting means, when the second power supply voltage is equal to or higher than a predetermined threshold value and is instructed to operate by a data carrying and processing function for communicating with an external information processing device, Alternatively, the second power supply voltage is selected as a power supply voltage required for the operation when it is instructed to operate by the function of communicating with an external data carrying and processing medium. Semiconductor integrated circuit device. 3. The chip according to claim 2, wherein a functional unit that realizes a data carrying and processing function and a functional unit that realizes a function of communicating with an external data carrying and processing medium are configured by one chip. Semiconductor integrated circuit device. 4. A switch, in response to a signal instructing to operate by a function of communicating with an external data carrying and processing medium, between a connection point of the rectifying means and the generating means and a grounding point. The control means further includes control means for controlling switching, wherein the control means turns off the switch when the signal is supplied, and the selection means selects the second power supply voltage as a power supply voltage required for operation. 3. The semiconductor integrated circuit device according to claim 2, wherein a leak current is prevented from flowing in by the generation means when the leakage current occurs. 5. A clock extracting means for extracting a first clock based on the carrier wave, a clock generating means for generating a second clock, and the first clock extracted by the clock extracting means, The clock selecting means further includes a clock selecting means for selecting one of the second clocks generated by the clock generating means as a clock serving as a reference for operation, and the clock selecting means includes the first clock by the clock extracting means. When the clock is extracted, the first clock is selected as the reference clock for operation, and when the first clock is not extracted by the clock extraction means, the second clock is selected as the reference clock for operation.
2. The semiconductor integrated circuit device according to claim 1, wherein the clock is selected. 6. Rectifying means for rectifying the received carrier wave, generating means for generating a first power supply voltage based on an output from the rectifying means, and the first power supply voltage generated by the generating means. When,
Selecting means for selecting any one of the supplied second power supply voltages as a power supply voltage required for operation, wherein the selecting means is configured such that when the second power supply voltage is equal to or less than a predetermined threshold value. A power supply required for operation when the first power supply voltage is selected as a power supply voltage required for operation, the second power supply voltage is equal to or higher than a predetermined threshold, and an instruction to operate with a predetermined function is given. A mobile terminal device having a semiconductor integrated circuit device for selecting the second power supply voltage as a voltage therein. 7. A rectifying unit that rectifies a received carrier wave for settlement caused by a predetermined transaction, a generating unit that generates a first power supply voltage based on an output from the rectifying unit, and the generating unit. Selecting means for selecting one of the generated first power supply voltage and the supplied second power supply voltage as a power supply voltage required for operation; and storage means for storing money amount information as consideration for a predetermined transaction. A payment method performed with a mobile terminal device comprising: a communication step of communicating with the mobile terminal device; and, by the processing of the communication step, the money amount information stored by the mobile terminal device. A payment method comprising: a read step of reading and a payment step of making a payment based on the amount information read by the processing of the read step.