JP2010061695A - Information processor - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To easily deal with a non-contact type IC card. <P>SOLUTION: A computer 10 includes a slot 22 for the non-contact type IC card for storing the non-contact type IC card 25. The slot 22 for the non-contact IC card is arranged in a position where the stored non-contact type IC card 25 is radio-communicable with an IC card reader/writer 21 disposed on the upper face part of a computer body 11. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to an information processing apparatus equipped with a communication device that performs wireless communication with a non-contact type IC card.

  In recent years, some information processing apparatuses such as personal computers are equipped with a communication apparatus that performs wireless communication with a non-contact type IC card. Some non-contact type IC cards have a function that can be used as a ticket in transportation such as a train or as electronic money in a general store or online shopping via a network.

  The non-contact type IC card transmits and receives data by generating electric power by electromagnetic induction based on radio waves transmitted from a communication device. Therefore, the non-contact type IC card cannot be used because it does not change the magnetic field because the magnetic field does not change if it is placed close to the communication device. When using a non-contact type IC card, a user needs to perform an operation (an operation of releasing after approaching a predetermined distance from a position away from the communication device) each time the user holds the communication device.

  Conventionally, a data communication method capable of copying the contents of a non-contact type IC card to another IC card has been considered (see Patent Document 1). In the data communication method described in Patent Document 1, two IC cards are superimposed on a reader / writer, and the reader / writer antenna and the two card antennas are coupled to each other, whereby data between the cards is recorded. Has been realized.

JP 2002-24778 A

  As described above, in the conventional information processing apparatus, when receiving and processing data from the non-contact type IC card, the user needs to hold the non-contact type IC card over a communication device provided in the information processing apparatus. It was. Therefore, when a non-contact type IC card is used a plurality of times, the same operation must be repeated each time, and handling is troublesome.

  Further, in the data communication method of Patent Document 1, copying between IC cards is realized by placing two IC cards on a reader / writer, but before executing copying, each IC card is copied. It was necessary to execute processing. That is, by placing the first IC card on the reader / writer, data is read from the first IC card and a predetermined process is executed, and then the placement of the second IC card is instructed. When the second IC card is placed on the reader / writer, the second IC card is recognized, and the contents stored in the memory are confirmed. That is, in the data communication method of Patent Document 1, an operation for placing two IC cards individually on a reader / writer is required. Therefore, when the operation of copying data between two IC cards is executed a plurality of times, an operation for placing the two IC cards on the reader / writer is required each time, and handling is troublesome. .

  The present invention has been made in consideration of the above-described circumstances, and an object thereof is to provide an information processing apparatus capable of easily handling a non-contact type IC card.

  In order to solve the above-described problems, the present invention provides a communication device that is provided in a housing and performs wireless communication with a non-contact type IC card, and stores the non-contact type IC card. The non-contact IC card and the communication device are placed on a housing means provided at a position where communication is possible, the first non-contact IC card housed by the housing means and the housing. Each of the second non-contact type IC cards radiates an induced magnetic field capable of generating an induced electric power, and is provided in the vicinity of the storage means. When the induction magnetic field is radiated by the magnetic field radiating means, the first non-contact IC card and the second non-contact IC card transmit and receive data at different timings by wireless communication, and the first non-contact IC card and the second non-contact IC card Non And executes processing for recorded on the a touch-type IC card a second non-contact type IC card data.

  According to the present invention, since wireless communication is performed with the communication device in a state where the non-contact type IC card is stored in the storage unit, it is possible to easily handle the non-contact type IC card.

The perspective view in the state where the display unit of computer 10 was opened. Sectional drawing in the AA in FIG. 1 is a block diagram showing a system configuration of a computer 10. FIG. The figure which shows about the relationship between the hardware for controlling the IC card reader / writer 21, and software. The block diagram which shows the structural example of the non-contact-type IC card. The figure which looked at the relative positional relationship of IC card reader / writer 21, non-contact type IC card 25a, and non-contact type IC card 25b from the side. The figure which looked at the positional relationship of IC card reader / writer 21 and built-in non-contact type IC card 25a, 25b from the top. The figure which shows the communication period of the two non-contact-type IC cards 25 and the IC card reader / writer 21. The flowchart which shows the built-in IC card detection process in this embodiment. The flowchart which shows the IC card process which performs card payment with the non-contact-type IC card 25 which has a charge payment function (electronic money etc.). The figure which shows the 1st IC card process which exchanges data between the two non-contact type IC cards 25a and 25b via the IC card reader / writer 21. A second IC card process for exchanging data between two external non-contact IC cards 25a1 and 25a2 via the IC card reader / writer 21 and the built-in non-contact IC card 25b is shown. Figure. The flowchart shown about a 1st IC card process. The flowchart shown about a 2nd IC card process.

Embodiments of the present invention will be described below with reference to the drawings.
First, with reference to FIG.1 and FIG.2, the structure of the information processing apparatus which concerns on embodiment of this invention is demonstrated. This information processing apparatus is realized, for example, as a notebook-type portable personal computer 10 (hereinafter simply referred to as a computer 10) that can be driven by a battery.

  FIG. 1 is a perspective view of the computer 10 with the display unit opened.

The computer 10 includes a computer main body 11 and a display unit 12. The display unit 12 incorporates a display device composed of an LCD (Liquid Crystal Display) 17, and the display screen of the LCD 17 is positioned substantially at the center of the display unit 12. A pair of speakers (tweeters) 19 a are arranged on both sides of the LCD 17.

  The display unit 12 is attached to the computer main body 11 so as to be rotatable between an open position where the upper surface of the computer main body 11 is exposed and a closed position where the upper surface is covered by the display unit 12. The computer main body 11 has a thin box-shaped housing to which a battery can be detachably mounted.

  A keyboard 13, a power button switch 14 for powering on / off the computer 10, a touch pad 15, an audio / video (AV) operation panel 16, an AV controller, and a volume control dial 18 are provided on the top surface of the casing of the computer main body 11. , And a pair of speakers 19b are arranged. The keyboard 13 includes a plurality of keys including four direction keys (up, down, left, and right) and other various keys (alphabetic keys, numeric keys, auxiliary keys, and the like).

  The computer 10 has an AV function for reproducing various media such as TV broadcast programs, moving image data, still images, and music. The AV operation panel 16 includes a plurality of buttons for controlling the AV function of the computer 10. Each of these buttons is composed of an electrostatic switch. In the center of each electrostatic switch, an LED translucent part is arranged.

The light from the LED provided corresponding to each electrostatic switch is emitted to the outside through the corresponding LED translucent part.

  The plurality of buttons on the AV operation panel 16 includes a TV button, a CD / DVD button, an LED on / off button, and the like. The TV button is a button for instructing activation of a TV function for viewing or recording a TV broadcast program. The CD / DVD button is a button for instructing activation of the CD / DVD function for reproducing the content stored in the CD medium or the DVD medium. The LED on / off button is a button for controlling each LED in the AV operation panel 16.

  In the computer 10 according to the present embodiment, an IC card reader / writer 21 (communication device) is provided on the upper surface of the computer main body 11. The IC card reader / writer 21 transmits and receives data to and from the non-contact type IC card 25 by wireless communication. The IC card reader / writer 21 generates a constant magnetic field when data transmission / reception with the non-contact type IC card 25 is executed. When the user holds (closes) the IC card reader / writer 21 over the IC card reader / writer 21, electric power is induced by the magnetic field generated by the IC card reader / writer 21. The IC card reader / writer 21 performs an operation for data transmission / reception by the induced power.

  Further, the computer 10 according to the present embodiment is provided with a non-contact type IC card slot 22 in which the non-contact type IC card 25 can be accommodated from the side of the casing of the computer main body 11 (the left side in FIG. 1). ing. The non-contact type IC card slot 22 is provided below the IC card reader / writer 21 provided on the upper surface of the casing of the computer main body 11. The non-contact type IC card slot 22 is connected to the IC card reader / writer 21 so that the non-contact type IC card 25 accommodated therein and the IC card reader / writer 21 can stably communicate with each other. It is provided at a close position.

  2 is a cross-sectional view taken along line AA in FIG. FIG. 2 shows a state in which the non-contact type IC card 25 accommodates the non-contact type IC card slot 22.

  As shown in FIG. 2, the non-contact type IC card 25 is housed in the computer main body 11 at a position close to the IC card reader / writer 21 by being housed in the non-contact type IC card slot 22.

  In the non-contact type IC card slot 22, for example, a card detection sensor 26 is provided at the innermost position. The card detection sensor 26 is for detecting whether or not the non-contact type IC card 25 is stored in the non-contact type IC card slot 22. The card detection sensor 26 is provided at a position where the end of the non-contact type IC card 25 comes into contact when the non-contact type IC card 25 is completely stored in the non-contact type IC card slot 22.

  However, since the non-contact type IC card 25 performs wireless communication with the IC card reader / writer 21, even if it is not completely stored in the non-contact type IC card slot 22, the IC card reader / writer Data can be sent to and received from 21. Therefore, the card detection sensor 26 only needs to be able to detect that the non-contact type IC card 25 has been accommodated to a position where wireless communication with the IC card reader / writer 21 is possible.

  In FIG. 2, a mechanism for stably holding the non-contact type IC card 25 inserted into the non-contact type IC card slot 22 inside, and the non-contact type IC card 25 are also non-contact type IC cards. Illustration of a mechanism for taking out from the slot 22 is omitted.

  In FIG. 2, the card detection sensor 26 is provided to physically detect the non-contact type IC card 25. However, the non-contact type IC card 25 is inserted into the non-contact type IC card slot 22 by other methods. You may make it detect having accommodated (For example, in FIG. 10, a built-in IC card detection process is shown). In this case, the card detection sensor 26 can be omitted from the configuration shown in FIG.

  In FIG. 2, it is described that the IC card reader / writer 21 is provided on the upper surface of the computer main body 11, but the antenna portion that transmits and receives radio waves to and from the non-contact type IC card 25 is a computer. What is necessary is just to be provided in the upper surface part of the main body 11. FIG. The configuration of the IC card reader / writer 21 other than the antenna portion may be arranged in another place and connected to the antenna by a cable or the like.

  Further, in order to stabilize the state of wireless communication between the IC card reader / writer 21 and the non-contact type IC card 25 accommodated in the non-contact type IC card slot 22, the upper surface of the non-contact type IC card slot 22 is used. The side may be formed of a member that does not interfere with wireless communication, or an opening may be provided. Further, in order to eliminate the influence of electromagnetic waves generated from other electronic components housed inside the computer main body 11, the IC card reader / writer 21 and the non-contact type IC card slot 22 (non-contact type IC card 25). You may provide the member which covers the circumference | surroundings.

  Next, the system configuration of the computer 10 will be described with reference to FIG.

  The computer 10 includes a CPU 111, a north bridge 114, a main memory 115, a graphics processing unit (GPU) 116, a south bridge 117, a BIOS-ROM 120, a hard disk drive (HDD) 121, an optical disk drive (ODD) 122, a sound controller 123, and a TV. A tuner 124, an embedded controller / keyboard controller IC (EC / KBC) 140, a power supply circuit 141, and the like are provided.

  The CPU 111 is a processor provided to control the operation of the computer 10. The CPU 111 loads an operating system (OS) 112 from the HDD 121 to the main memory 115, an application program 113 using the non-contact type IC card 25, and the like. Run various applications. Further, the CPU 111 also executes a basic input / output system (BIOS) stored in the BIOS-ROM 120.

  The north bridge 114 is a bridge device that connects the local bus of the CPU 111 and the south bridge 117. The north bridge 114 also includes a memory controller that controls access to the main memory 115. The north bridge 114 also has a function of executing communication with the graphics processing unit (GPU) 116 via a PCI Express bus or the like.

  The graphics processing unit (GPU) 116 is a display controller that controls the LCD 17 used as a display monitor of the computer 10. The GPU 116 generates a video signal that forms a screen image to be displayed on the LCD 17 from display data written in the video memory (VRAM) 116A by the OS or an application program.

  The south bridge 117 includes an IDE (Integrated Drive Electronics) controller and a Serial ATA controller for controlling the hard disk drive (HDD) 121 and the optical disk drive (ODD) 122.

  The sound controller 123 is a sound source device, and executes processing for outputting sounds corresponding to various audio data from the speakers 19a and 19b. The TV tuner 124 receives broadcast program data broadcast by a TV broadcast signal.

  The embedded controller / keyboard controller IC (EC / KBC) 140 is a one-chip microcomputer in which an embedded controller for power management and a keyboard controller for controlling the keyboard (KB) 13 and the touch pad 15 are integrated. . The EC / KBC 140 is always supplied with operating power from the power circuit 141 even when the computer 10 is powered off. The EC / KBC 140 functions as a controller for controlling the AV operation panel 16, the AV controller 20, and the IC card reader / writer 21. Communication between the EC / KBC 140 and the AV controller 20 is executed, for example, via a serial bus or the like.

  The EC / KBC 140 has a function of powering on / off the computer 10 in accordance with the operation of the power button switch 14 by the user. The power-on / power-off control of the computer 10 is executed by the joint operation of the EC / KBC 140 and the power supply circuit 141. The power supply circuit 141 generates an operation power supply for each component using power from the battery 142 attached to the computer main body 11 or power from the AC adapter 143 connected to the computer main body 11 as an external power supply.

  Next, a relationship between hardware and software for controlling the IC card reader / writer 21 will be described with reference to FIG.

  As described above, the keyboard 13, the touch pad 15, the IC card reader / writer 21 and the like are connected to the EC / KBC 140. The key code corresponding to the pressed key on the keyboard 13 is sent to the application program via the EC / KBC 140 and the OS 112. Data input from the non-contact type IC card 25 by the IC card reader / writer 21 is sent to the application program 113 using the non-contact type IC card 25 via, for example, the EC / KBC 140 and the OS 12.

  The OS 112 controls the operation of the IC card reader / writer 21 via the EC / KBC 140 in accordance with an instruction from the application program 113. For example, it is assumed that the OS 112 can generate an induced magnetic field for the IC card reader / writer 21 in response to an instruction from the application program 113. That is, when the built-in non-contact type IC card 25 is stored in the non-contact type IC card slot 22 (hereinafter, the built-in non-contact type IC card 25 in this state is referred to as a built-in non-contact type IC card 25). ) Cannot generate an induced power with a constant magnetic field radiated from the IC card reader / writer 21. Therefore, when executing data transmission / reception with the built-in non-contact type IC card 25, the OS 112 generates an induced magnetic field capable of generating an induced power in the built-in non-contact type IC card 25 in a stopped state. Generated by the writer 21.

  If the IC card reader / writer 21 is provided with a magnetic field radiation function that can arbitrarily radiate not only a constant magnetic field but also an induced magnetic field, the IC card reader / writer 21 is controlled as described above. Thus, an induced magnetic field can be radiated. On the other hand, when the IC card reader / writer 21 has only a magnetic field radiation function capable of radiating only a fixed magnetic field, the IC card reader / writer 21 is located in the vicinity of the non-contact type IC card slot 22 (and the IC card reader / writer 21). Further, a configuration in which a magnetic field radiation function for radiating an induction magnetic field may be provided. This magnetic field radiation function includes an antenna installed near the non-contact type IC card slot 22 and is driven by a controller that can be controlled by the OS 112, for example. By generating an induced magnetic field by this magnetic field radiation function, the non-contact type IC card 25 is in a state where electric power is induced and wireless communication with the IC card reader / writer 21 is possible.

Next, the configuration of the non-contact type IC card 25 will be described.
FIG. 5 is a block diagram illustrating a configuration example of the non-contact type IC card 25. The non-contact type IC card 25 is provided with, for example, an antenna (loop antenna) 30 and a capacitor 31 as shown in the figure, and transmits and receives signals to and from the IC card reader / writer 21.

  The interface unit 37 detects a signal received via the antenna 30 and outputs the signal to the demodulation unit 38, and transmits the signal modulated by the modulation unit 40 from the loop antenna 30. Further, the interface unit 37 stabilizes the power induced by the antenna 30 and supplies it to each unit. The interface unit 37 generates a clock or the like necessary for operation and supplies it to each unit.

  The CPU 33 develops a control program stored in the ROM 34 in the RAM 35 and controls the entire operation of the non-contact type IC card 25. For example, when the electromagnetic wave radiated from the IC card reader / writer 21 is received by the antenna 30 and power is supplied from the interface unit 37, the CPU 33 sets the card ID as identification information set in the EEPROM 36 or the ROM 34. And other data are transmitted to the IC card reader / writer 21 through the data transmission unit 41. The CPU 33 processes data from the IC card reader / writer 21 input through the data receiving unit 39. The CPU 33 not only transmits the card ID to the IC card reader / writer 21 (computer 10), but also performs an authentication process with the IC card reader / writer 21 and encrypts / decrypts data to be transmitted / received. Various processes such as processes are executed. For example, when the non-contact type IC card 25 is used as electronic money, the CPU 33 executes processing for managing electronic money (remaining money). The CPU 33 manages the data indicating the balance by recording it in the EEPROM 36.

Next, the positional relationship between the IC card reader / writer 21 mounted on the computer 10 and the non-contact type IC card 25 will be described.
FIG. 6 shows an IC card reader / writer 21 installed in the casing of the computer main body 11, a non-contact type IC card 25 a used outside the computer main body 11, and a non-contact type IC card slot 22. It is the figure which looked at the relative positional relationship with the non-contact-type IC card 25b from the side. FIG. 7 is a top view of the positional relationship between the IC card reader / writer 21 and the external and built-in non-contact IC cards 25a and 25b.

  The IC card reader / writer 21 has directivity capable of stably transmitting and receiving electromagnetic waves (signals) in the vertical direction when the computer 10 is installed horizontally. The non-contact type IC card slot 22 is provided in the lower part of the IC card reader / writer 21 so that the non-contact type IC card 25a accommodated in the non-contact type IC card slot 22 can be used in a stable state. Can be sent and received. Further, the non-contact type IC card 25a is used so that the user holds it over the position where the IC card reader / writer 21 is provided. Therefore, the IC card reader / writer 21 can perform wireless communication with the two non-contact type IC cards 25a and 25b in each of the upward and downward directions where signals can be transmitted and received in a stable state.

  In the computer 10 according to the present embodiment, not only the non-contact type IC cards 25a and 25b are used alone, but also two non-contact type IC cards 25a and 25b are simultaneously used as shown in FIGS. Can be used. When two built-in non-contact type IC cards 25a and 25b are used simultaneously, the non-contact type IC card 25a is held over the IC card reader / writer 21 with the non-contact type IC card 25b previously stored. In a state where the non-contact type IC card 25b is stored in the first form, the non-contact type IC card 25a is placed on the upper surface of the computer main body 11 at the position where the IC card reader / writer 21 is provided. There is a second form to use.

Next, the timing of wireless communication between the IC card reader / writer 21 and each non-contact type IC card 25a, 25b when two non-contact type IC cards 25a, 25b are used simultaneously will be described.
FIG. 8 is a diagram showing a communication period between the two non-contact type IC cards 25 and the IC card reader / writer 21. Here, the case where it uses with the 2nd form mentioned above is demonstrated to an example.

  The IC card reader / writer 21 generates a constant magnetic field when the non-contact type IC card 25 is accommodated in the non-contact type IC card slot 22 or placed on the computer main body 11. While it is, data cannot be transmitted to or received from the non-contact type IC card 25.

  In this case, in response to a request from the OS 112 (application program 113), the IC card reader / writer 21 generates an induction magnetic field that can generate power for the non-contact type IC card 25 as shown in FIG. generate. As a result, the non-contact type IC cards 25a and 25b inside and outside the computer main body 11 generate power and start an operation for data transmission / reception with the IC card reader / writer 21 (FIG. 8 (1)). (2)).

  At this time, when the contactless IC card 25 receives a signal from the IC card reader / writer 21 and starts operation, for example, it generates a random number and transmits / receives data at a timing according to the random value. Start operation. That is, the non-contact type IC card 25 starts an operation for data transmission / reception with the IC card reader / writer 21 at random timing determined individually. For this reason, even if the IC card reader / writer 21 generates an induction magnetic field and the two non-contact type IC cards 25a and 25b generate power simultaneously and start operation, the operation for data transmission / reception starts. Timing can be shifted.

  For example, FIG. 8A shows a communication period of the first non-contact type IC card 25 that has started the data transmission / reception operation. As shown in FIG. 8A, the first non-contact type IC card 25 executes communication with the IC card reader / writer 21 after the time (RND1) has elapsed since the start of operation. On the other hand, FIG. 8B shows a communication period of the second non-contact type IC card 25 that starts data transmission / reception later. As shown in FIG. 8B, the second non-contact type IC card 25 starts an operation for data transmission / reception after elapse of a time (RDN2) longer than (RND1). That is, the second non-contact type IC card 25 performs carrier sense after (RDN2) has elapsed. The second non-contact type IC card 25 starts communication with the IC card reader / writer 21 after the communication with the IC card reader / writer 21 by the first non-contact type IC card 25 is completed.

Next, a method for detecting that the non-contact type IC card 25 is stored in the non-contact type IC card slot 22 will be described.
When the non-contact type IC card 25 is stored in the non-contact type IC card slot 22, in order to communicate with the non-contact type IC card 25, as described above, the IC card reader / writer 21 An induced magnetic field needs to be generated. The computer 10 detects whether or not the non-contact type IC card 25 is stored in the non-contact type IC card slot 22 in order to determine whether the IC card reader / writer 21 needs to generate an induction magnetic field.

  (A) A method of detecting using the card detection sensor 26.

  As shown in FIG. 2, by mounting a card detection sensor 26 in the non-contact type IC card slot 22, it is detected that the non-contact type IC card 25 is stored in the non-contact type IC card slot 22. The card detection sensor 26 notifies the CPU 111 that the non-contact type IC card 25 is stored, for example, through the EC / KBC 140. The OS 112 or the application program 113 records data indicating that the non-contact type IC card 25 is built in, and manages the state of the non-contact type IC card 25.

  (B) A method of detecting by a built-in IC card detection process.

  The computer 10 manages whether or not the non-contact type IC card 25 is accommodated in the non-contact type IC card slot 22 by executing the built-in IC card detection process shown in the flowchart of FIG. The built-in IC card detection process may be executed by the application program 113, or may be executed by the OS 112 in response to a request from the application program 113.

  Hereinafter, the built-in IC card detection process will be described with reference to the flowchart of FIG.

  The IC card reader / writer 21 generates a constant magnetic field as a steady state (step A1). In this state, when the non-contact type IC card 25 is brought close to the IC card reader / writer 21, data can be transmitted and received between the IC card reader / writer 21 and the non-contact type IC card 25.

  When data is received from the non-contact type IC card 25 (step A2), the computer 10 receives and records the card ID from the non-contact type IC card 25 through the IC card reader / writer 21 (step A2). Step A3). Here, the card ID is received when the external non-contact type IC card 25a is brought close to the IC card reader / writer 21, or the non-contact type IC card 25b is inserted into the non-contact type IC card slot 22. Therefore, it cannot be determined whether the card ID is received.

  Here, the computer 10 generates an induced magnetic field by the IC card reader / writer 21 after a predetermined time has elapsed (step A4). The fixed time is usually a sufficient time (for example, about 2 seconds) when the operation to the IC card reader / writer 21 is completed when the external non-contact type IC card 25a is used.

  If no data is received from the non-contact type IC card 25 when the induction magnetic field is generated after a certain time (step A5, No), the computer 10 does not contact the non-contact type IC card slot 22 with the non-contact type IC card. It is determined that the IC card 25 is not stored.

  On the other hand, when the induction magnetic field is generated after a certain time, and there is data reception from the non-contact type IC card 25 (step A5, Yes), the computer 10 receives the card ID received here and the previous one. Is compared with the received card ID (step A6). If the card IDs are not the same (step A7, No), the computer 10 determines that the non-contact type IC card 25 is not stored in the non-contact type IC card slot 22.

  On the other hand, if the card IDs are the same (step A7, Yes), the computer 10 determines that the non-contact type IC card 25 is stored in the non-contact type IC card slot 22, Data indicating that the contact IC card 25 is in the built-in state is recorded (step A8).

  That is, the card ID is received by the IC card reader / writer 21 when the non-contact type IC card 25 is stored in the non-contact type IC card slot 22, and then the same non-contact type IC card 25 is received by the non-contact type IC card. If the slot 22 remains in the built-in state, a card ID is received from the same non-contact type IC card 25 by generating an induction magnetic field. Therefore, when the same card ID is received in a constant magnetic field and an induced magnetic field, it can be determined that the non-contact type IC card 25 is stored in the non-contact type IC card slot 22.

  Thereafter, the computer 10 generates a constant magnetic field by the IC card reader / writer 21 (step A9). Here, when the card ID is received from the non-contact type IC card 25 (step A10, Yes), and this card ID is the same as the card ID of the non-contact type IC card 25 in which it is built (step A11, Yes), the computer 10 determines that the non-contact type IC card 25 has been removed from the non-contact type IC card slot 22. The computer 10 erases data indicating that the non-contact type IC card 25 is in a built-in state (step A12).

  In this way, the magnetic field generated from the IC card reader / writer 21 is switched between a constant magnetic field and an induction magnetic field, and the non-contact type IC is read based on the card ID read from the non-contact type IC card 25 at each time. It can be detected that the non-contact type IC card 25 is stored in the card slot 22.

  In the above description, it is assumed that the contactless IC card 25 is stored in the contactless IC card slot 22 in advance. However, in the application processing executed by the application program 113, the contactless IC card is detected. If the card 25 does not need to be stored in the non-contact type IC card slot 22, that is, if data can be read from either the external or internal non-contact type IC card 25a, 25b, the above-described processing is performed. Can be omitted.

  In this case, an induction magnetic field is generated when data transmission / reception with the non-contact type IC card 25 becomes necessary. At this time, if no data is received from the non-contact type IC card 25, it is determined that the non-contact type IC card 25 is not stored in the non-contact type IC card slot 22, and the IC card reader / writer is determined. A constant magnetic field is generated from 21. The user waits for data to be received from the non-contact type IC card 25 by operating the non-contact type IC card 25 over the IC card reader / writer 21.

Next, specific processing using the non-contact type IC card 25 of the computer 10 in the present embodiment will be described.
FIG. 10 is a flowchart showing an IC card process for executing card payment using a non-contact type IC card 25 having a charge settlement function (electronic money or the like).

  First, the computer 10 executes application processing related to card payment by the application program 113 (step B1). For example, the application program 113 determines the amount to be settled by the non-contact type IC card 25 in accordance with an instruction from the user. Here, when an instruction for settlement by the non-contact type IC card 25 is input by the user, that is, when there is an access request to the non-contact type IC card 25 (step B2, Yes), the application program 113 passes through the OS 112. Thus, communication with the non-contact type IC card 25 is executed by the IC card reader / writer 21.

  Here, when the non-contact type IC card 25 is built in the computer main body 11 by the non-contact type IC card slot 22 (step B3, Yes), the application program 113 (or OS 112) is the IC card reader / writer 21. In this way, an induced magnetic field is generated (step B4) so that data can be transmitted to and received from the built-in non-contact type IC card 25. It is assumed that whether or not the non-contact type IC card 25 is built in is previously detected by the card detection sensor 26 or the built-in IC card detection process described above.

  Here, when data is received from the non-contact type IC card 25 (card ID or the like) (step B5, Yes), the application program 113 is connected to the non-contact type IC card 25 by the IC card reader / writer 21. Data transmission / reception related to card payment is executed between the two, and processing for card payment is executed for the data received from the non-contact type IC card 25 (step B8). For example, when the non-contact type IC card 25 is equipped with a prepaid payment function, data after settlement (that is, the balance) is calculated, and the data is non-contact type by the IC card reader / writer 21. It transmits to the IC card 25 (step B9).

  When the non-contact type IC card 25 is not built in the computer main body 11 (step B3, No), or when no data is received from the non-contact type IC card 25 even if an induction magnetic field is generated (step B5, In No), the application program 113 (OS 112) generates a constant magnetic field by the IC card reader / writer 21 (step B6) and waits for data reception from the external non-contact type IC card 25a. That is, the user waits for an operation to bring the non-contact type IC card 25a close to the IC card reader / writer 21.

  Here, when data is received from the non-contact type IC card 25 (step B7, Yes), the application program 113 performs processing on the data received from the non-contact type IC card 25 in the same manner as described above. This is executed (step B8), and the processed data is transmitted to the non-contact type IC card 25 by the IC card reader / writer 21 (step B9).

  As described above, in the computer 10 according to this embodiment, if the non-contact type IC card 25 is stored in the non-contact type IC card slot 22, the user inserts the non-contact type IC card 25 into the IC card at the time of card settlement. Card processing can be executed without performing an operation of holding (approaching) the reader / writer 21. Therefore, even when card payment is required multiple times, the non-contact IC card 25 can be kept in the non-contact IC card slot 22, so that the user can handle the non-contact IC card 25. It becomes easy.

Next, a specific example in which two non-contact type IC cards 25 are simultaneously used by the computer 10 in the present embodiment will be described.
In the computer 10 according to the present embodiment, the IC card reader / writer 21 transmits / receives data to / from the external non-contact type IC card 25a while the non-contact type IC card 25b is housed in the non-contact type IC card slot 22. Is possible. By using this, the first IC card process shown in FIG. 11 and the second IC card process shown in FIG. 12 can be executed.

  FIG. 11 shows a first IC card process for exchanging data between two non-contact type IC cards 25a and 25b via the IC card reader / writer 21. For example, the non-contact type IC cards 25a and 25b are equipped with an electronic money function and can be charged with a monetary value. Here, for example, a process of transferring the monetary value charged in the built-in non-contact type IC card 25b to the external non-contact type IC card 25a is executed. Further, it is assumed that the external non-contact type IC card 25a is placed on the computer main body 11 at a position where the IC card reader / writer 21 is provided.

  FIG. 12 shows a second example in which data is exchanged between two external non-contact type IC cards 25a1 and 25a2 via the IC card reader / writer 21 and the built-in non-contact type IC card 25b. IC card processing is shown. Here, for example, a process of transferring a point recorded on the non-contact type IC card 25a1 to another non-contact type IC card 25a2 via the built-in non-contact type IC card 25b.

  11 and 12 show the relationship between the IC card reader / writer 21 and the non-contact type IC cards 25a and 25b, and do not show physical relative positions.

First, the first IC card process shown in FIG. 11 will be described with reference to the flowchart shown in FIG.
The application program 113 sets the non-contact type IC card 25 to be processed by a user operation on the keyboard 13 and the touch pad 15 (step C1). For example, the computer 10 registers in advance the processing of the application program 113 for the non-contact type IC card 25 to be subjected to the first IC card processing. That is, the card ID is read from the non-contact type IC card 25 and recorded (step C2). Then, the user is allowed to select a monetary value charge source and destination from a plurality of non-contact type IC cards 25 (card IDs) registered in advance.

  The application program 113 sets card processing contents. Here, the monetary value (amount) to be transferred from the non-contact type IC card 25 that is the charge source of the monetary value to the destination non-contact type IC card 25 is set in accordance with an instruction from the user.

  Note that data relating to a person who uses each contactless IC card 25 is recorded in association with the card ID. Thereby, for example, an instruction can be given to move the monetary value of 5000 yen from the non-contact type IC card 25 owned by the father to the non-contact type IC card 25 owned by the child.

  When the processing content is set in this way and execution of the processing is instructed, the application program 113 reads the card ID (charge source, destination) of the contactless IC card 25 to be processed and the monetary value (amount) to be transferred. Is sent to the IC card reader / writer 21 and an induced magnetic field is generated by the IC card reader / writer 21 via the OS 112 (step C3).

  When the IC card reader / writer 21 receives data including the card ID and the charge amount from the first non-contact type IC card 25 (step C4), the processing for the data received from the first non-contact type IC card 25 is performed. Is executed (step C5).

  For example, when the card ID received from the first contactless IC card 25 is a card ID set as a charge source, the amount of movement instructed from the application program 113 is subtracted from the current charge amount. The IC card reader / writer 21 transmits the processed data from which the amount of movement has been deducted to the first non-contact type IC card 25 (step C6).

  On the other hand, when the IC card reader / writer 21 receives the data including the card ID and the charge amount from the second contactless IC card 25 (step C7), the data received from the second contactless IC card 25 is received. Is executed (step C8).

  For example, when the card ID received from the second non-contact type IC card 25 is the card ID set as the destination, the charge of the first non-contact type IC card 25 is added to the read charge amount. The amount subtracted from the amount (the amount designated by the application program 113) is added to the current charge amount. The IC card reader / writer 21 transmits the processed data to the second non-contact type IC card 25 (step C9).

  In the above description, the case where data is first received from the non-contact type IC card 25 (the built-in non-contact type IC card 25b) that is the charge source has been described. In some cases, data from the IC card 25 (external non-contact type IC card 25a) is received. In this case as well, the processing to be performed on the non-contact type IC card 25 at the charge source and the destination may be executed in the same manner as described above.

  In this way, the non-contact type IC card 25b built in the non-contact type IC card slot 22 and the external non-contact type IC card 25a can be contacted via the IC card reader / writer 21. Data can be exchanged by simplifying the handling of the IC cards 25a and 25b.

  In addition, since the IC card reader / writer 21 exchanges data between the non-contact type IC card 25a and the non-contact type IC card 25b, the validity of the data is guaranteed. That is, when data is exchanged between the non-contact type IC cards 25a and 25b and the IC card reader / writer 21, processing such as authentication processing and encryption / decryption processing is involved. Tampering can be prevented.

  In the process shown in FIG. 13, the application program 113 completes the process by executing data transmission / reception with respect to the two non-contact type IC cards 25a and 25b by generating an induction magnetic field once. However, data reception from the non-contact type IC cards 25a and 25b and data transmission to the non-contact type IC cards 25a and 25b may be processed separately.

  For example, data is received from the two non-contact type IC cards 25a and 25b by the induced magnetic field generated for the first time, and the processing for the data received from each is executed. At this time, what kind of processing is to be executed on the data received from which non-contact type IC card 25 is executed according to the card ID and processing content instructed from the application program 113 in advance. Thereafter, the IC card reader / writer 21 generates a second induction magnetic field. At this time, the IC card reader / writer 21 transmits the processed data to each based on the card ID received from the non-contact type IC card 25a, 25b.

  When the induction magnetic field is generated at the second time, as described with reference to FIG. 8, the IC card reader / writer 21 is not contacted in the order different from that at the time when the induction magnetic field is generated at the first time. Although there is a possibility that communication is performed with the type IC cards 25a and 25b, it is possible to achieve consistency based on the card ID.

Next, the second IC card process shown in FIG. 12 will be described with reference to the flowchart shown in FIG.
The application program 113 sets the non-contact type IC card 25 to be processed by a user operation on the keyboard 13 or the touch pad 15 (step D1). The setting of the non-contact type IC card 25 to be processed is executed in the same manner as the first IC card process described above (step D2). Next, the application program 113 sets card processing contents in accordance with an instruction from the user. Here, for example, it is assumed that all points recorded on the non-contact type IC card 25a1 communicated first are moved to the non-contact type IC card 25a2 communicated later.

  When the processing content is set and the execution of the processing is instructed, the application program 113 stores the card ID of the contactless IC card 25 to be processed and data indicating the processing content (movement of all points) on the IC card. The reader / writer 21 is notified, and a constant magnetic field is emitted by the IC card reader / writer 21 via the OS 112 to enable wireless communication with the external non-contact type IC card 25.

  When data is received from the first external non-contact type IC card 25 (non-contact type IC card 25a1) (step D3), the IC card reader / writer 21 receives the data received from the non-contact type IC card 25a1. Is executed (step D4). That is, it is confirmed that the card is a non-contact type IC card 25a1 to be processed based on the card ID, and data indicating the recorded points is acquired. The points recorded on the non-contact type IC card 25a1 are set to zero.

  Here, the IC card reader / writer 21 generates an induction magnetic field (step D5) and receives the non-contact type IC card 25b built in the non-contact type IC card slot 22 from the non-contact type IC card 25a1. The received points are transmitted (step D6). The non-contact type IC card 25b records the points received from the IC card reader / writer 21.

  Next, the IC card reader / writer 21 applies a constant magnetic field so as to enable data communication with the external second non-contact type IC card 25 (non-contact type IC card 25a2) to which the point is moved. Radiates and waits for data reception.

  Here, the IC card reader / writer 21 receives the card ID from the external non-contact type IC card 25 and confirms that it is the non-contact type IC card 25a2 to be processed (step D7). An induction magnetic field is generated to read the points recorded on the non-contact type IC card 25b (step D8).

  The IC card reader / writer 21 receives point data from the non-contact type IC card 25b (step D9) and transmits this data to the non-contact type IC card 25a2 (step D10). The non-contact type IC card 25a2 records the point data received from the IC card reader / writer 21.

  In this manner, data can be exchanged between the two non-contact type IC cards 25a1 and 25a2 via the non-contact type IC card 25b built in the non-contact type IC card slot 22. . Since the non-contact type IC card 25b can be processed while being accommodated in the non-contact type IC card slot 22, even if three non-contact type IC cards 25 are used, the handling is not complicated. . In addition, since data is exchanged via the non-contact type IC card 25b, data validity is guaranteed.

  In the above description, one non-contact type IC card slot 22 is provided, but a plurality of slots can be provided so that a plurality of non-contact type IC cards 25 can be stored in the casing of the computer main body 11 at the same time. You may do it. For example, an IC card reader / writer 21 (antenna unit) is installed in the housing of the computer main body 11, and one non-contact type IC card slot 22 is installed above and below the IC card reader / writer 21. In this case, a plurality of non-contact type IC cards 25 can be built in the casing of the computer main body 11 at the same time. In this state, communication with the plurality of non-contact type IC cards 25 is performed by the IC card reader / writer 21. It can be carried out.

  In the above description, the non-contact type IC card slot 22 allows the non-contact type IC card 25 to be detachable. However, the non-contact type IC card 25 may be fixedly stored and cannot be taken out. it can.

  In addition, when the non-contact type IC card slot 22 is configured to be detachable from the non-contact type IC card 25, a lock mechanism may be provided to prevent the non-contact type IC card 25 from being easily removed. That is, when the non-contact type IC card 25 can be used as electronic money, it may be illegally used if it is passed to another person due to theft or the like. For this reason, even if the user is away from the computer 10, the non-contact type IC card 25 cannot be easily removed from the non-contact type IC card slot 22 by another person. For example, when the computer 10 is equipped with an authentication function for authenticating a user, the lock is released only when the authentication function confirms that the user is a valid user, and the slot for the non-contact type IC card The non-contact type IC card 25 can be taken out from 22.

  In the above description, the non-contact type IC card 25 accommodated in the non-contact type IC card slot 22 is connected by wireless communication via the IC card reader / writer 21, but is physically connected. It is good also as a structure. In this case, the non-contact type IC card 25 is provided with an external terminal that can be electrically connected. This external terminal can be provided on either the front or back side of the non-contact type IC card 25 or on any side. The non-contact type IC card slot 22 is provided with a connection terminal at a position where the non-contact type IC card 25 comes into contact with the external terminal provided when the non-contact type IC card 25 is accommodated. Thereby, when the non-contact type IC card 25 is stored in the non-contact type IC card slot 22, the external terminal of the non-contact type IC card 25 and the connection terminal of the non-contact type IC card slot 22 are electrically connected. Connected.

  The computer 10 can detect that the non-contact type IC card 25 is stored in the non-contact type IC card slot 22 by being electrically connected to the non-contact type IC card 25. Further, the computer 10 can control the operation of the non-contact type IC card 25. For example, the computer 10 can switch the non-contact type IC card 25 to an operable state or an impossible state by applying a predetermined voltage to the non-contact type IC card 25. As a result, the computer 10 makes the non-contact type IC card 25 stored in the non-contact type IC card slot 22 inoperable according to the processing content set by the application, for example. Wireless communication can be performed only with the non-contact type IC card 25.

  In the above description, the computer main body 11 is provided with the IC card reader / writer 21 that can read / write data from / to the non-contact type IC card 25, but the computer 10 (application program 113). In the case where the IC card processing executed by (2) makes it unnecessary to write data to the non-contact type IC card 25, an IC card reader that reads data from the non-contact type IC card 25 may be mounted.

  In the above description, the notebook type portable personal computer 10 is described as an example. However, the present invention is applied to various information processing apparatuses in which the IC card reader / writer 21 (or IC card reader) is mounted. It is possible to apply.

  Further, the present invention is not limited to the above-described embodiments as they are, and can be embodied by modifying the constituent elements without departing from the scope of the invention in the implementation stage. In addition, various inventions can be formed by appropriately combining a plurality of components disclosed in the embodiment. For example, some components may be deleted from all the components shown in the embodiment. Furthermore, you may combine a component suitably in different embodiment.

  DESCRIPTION OF SYMBOLS 10 ... Computer, 11 ... Computer main body, 22 ... Non-contact type IC card slot, 23 ... IC card reader / writer, 25 ... Non-contact type IC card.

Claims (7)

A communication device for wireless communication with a non-contact type IC card provided in the housing;
A storage means for storing the non-contact type IC card, the storage means provided at a position where the stored non-contact type IC card and the communication device can communicate;
Radiating an induced magnetic field capable of generating an induced electric power in each of the first non-contact type IC card stored by the storage means and the second non-contact type IC card placed on the housing; Magnetic field radiation means provided in the vicinity of the storage means,
The communication device transmits and receives data at different timings by wireless communication with each of the first non-contact type IC card and the second non-contact type IC card when the induction magnetic field is radiated by the magnetic field radiating means. An information processing apparatus that performs processing on data recorded in the first non-contact type IC card and the second non-contact type IC card.   The information processing apparatus according to claim 1, wherein the magnetic field radiating unit is provided in the communication apparatus. The communication device is provided on the upper surface of the housing,
The storage means is located below the communication device so that the non-contact IC card placed on the communication device and the stored non-contact IC card are symmetrical with respect to the communication device. The information processing apparatus according to claim 1, wherein the information processing apparatus is provided in a section.   The information processing apparatus according to claim 1, wherein the storage unit stores the non-contact type IC card so as to be removable.   2. The information processing apparatus according to claim 1, further comprising detection means for detecting that the non-contact type IC card is stored in the storage means. The detection means includes
And a sensor for detecting that the non-contact type IC card is stored in contact with the non-contact type IC card when the non-contact type IC card is stored in the storage unit. Item 6. The information processing device according to Item 5. The detection means includes
Identification information recording means for recording the first identification information received from the non-contact type IC card by radiating a magnetic field by the magnetic field radiating means;
Magnetic field radiation control means for radiating a magnetic field by the magnetic field radiation means after a certain period of time when the first identification information is recorded by the identification information recording means;
When the second identification information received from the non-contact type IC card after radiating the magnetic field by the magnetic field radiation control means matches the first identification information recorded in the identification information recording means, 6. The information processing apparatus according to claim 5, further comprising: a determination unit that determines that the non-contact type IC card is stored in the storage unit.

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