JP6819201B2 - Electronic information storage medium, IC card, setting information transmission method, and setting information transmission program - Google Patents

Description

The present invention relates to the technical field of electronic information storage media such as IC chips.

In short-range wireless communication, a non-contact communication compatible IC card used by being attached to a mobile terminal has a contact interface for contact communication and a non-contact interface for non-contact communication via the antenna of the mobile terminal. The non-contact interface is connected to a chip on the mobile terminal side called a CLF (Contactless frontend). The CLF is a front end that manages an antenna used for short-range wireless communication, and relays communication between a non-contact R / W (Reader / Writer) and a non-contact communication compatible IC card.

When a mobile terminal having a non-contact communication compatible IC card and CLF approaches the non-contact R / W to a communicable distance, an initial response of communication is performed between the CLF and the non-contact R / W. When this initial response is properly performed, the communication parameters used by the CLF and the non-contact R / W are set thereafter, and communication between the non-contact communication compatible IC card and the non-contact R / W becomes possible. ..

The CLF requires setting information (information created based on various information such as the corresponding communication protocol and bit rate) of the contactless communication compatible IC card in order to appropriately perform the initial response. Therefore, the non-contact communication compatible IC card transmits the setting information to the CLF through the non-contact interface at the time of initializing the communication channel between the non-contact communication compatible IC card and the CLF. Then, the CLF manages the received setting information by associating it with the communication channel with the contactless communication compatible IC card. The non-contact communication compatible IC card can transmit the setting information to the CLF at any timing as long as the communication channel with the CLF has already been opened. As an example of transmission timing, Patent Document 1 discloses that setting information is transmitted to CLF in response to a request from CLF.

When a plurality of applications are mounted on the non-contact communication compatible IC card, the setting information to be transmitted to the CLF is created by reflecting the information of the application that processes the communication. In a non-contact communication compatible IC card equipped with a plurality of applications, a method for calculating setting information for transmission to the CLF is standardized (GP Amd.C). In this method, information (Protocol Data) that specifies the signals that can be processed by the application is given to each application.

In addition, the user can set the availability and priority of the interface for the application, and the technique relating to this is disclosed in Patent Document 2. The non-contact communication compatible IC card creates setting information by reflecting information such as Protocol Data and priority of the application to be mounted. This creation process requires a certain amount of time because it is necessary to scan the information of all applications that use the non-contact interface.

The user can temporarily change the availability and priority of the interface. At this time, the non-contact communication compatible IC card creates setting information reflecting the temporarily changed information, transmits it to the CLF, and has the CLF make an initial response based on the setting information. As a result, communication according to the changed content becomes possible between the non-contact communication compatible IC card and the non-contact R / W.

Japanese Unexamined Patent Publication No. 2012-84156 Japanese Unexamined Patent Publication No. 2010-218450

Here, communication according to the changed content is completed between the non-contact communication compatible IC card and the non-contact R / W, and then communication is performed between the non-contact communication compatible IC card and the non-contact R / W. In order to perform communication according to the contents of the normal time before the change, the setting information reflecting the normal time information is transmitted to the CLF again, and the CLF is initially responded to the non-contact R / W. I need to get it.

However, since it takes a certain amount of time to recreate the setting information in order to transmit the setting information reflecting the normal information to the CLF, for example, the communication start is delayed when the mobile terminal is held in the non-contact R / W. There is a problem that the usability deteriorates. This delay occurs because the CLF waits for the reception of the setting information from the non-contact communication compatible IC card when the non-contact communication compatible IC card and the non-contact R / W make an initial response before the start of communication.

Therefore, the present invention temporarily changes the application information for the setting information created based on the application information related to the application and transmitted to the relay device such as CLF, and creates and relays the setting information reflecting the change. Even if it is sent to the device, the communication setting based on the setting information created based on the application information before the change is immediately made, and the start of communication with the terminal device such as the non-contact R / W is delayed. The purpose is to provide an electronic information storage medium or the like without a device.

In order to solve the above problems, the invention according to claim 1 is an electronic information storage medium including a memory for storing application information related to an application and capable of communicating with a terminal device via a relay device. A creating means for creating setting information used by the relay device for communication setting with the terminal device and storing it in the memory, and a transmitting means for transmitting the setting information to the relay device at a predetermined timing. In preparation, when the creation means is instructed to temporarily change the application information, the creation means creates temporary setting information which is the temporary setting information based on the application information to which the temporary change is added. Then, the memory is stored separately from the normal setting information, which is the normal setting information created based on the application information before the temporary change is made, and the memory is stored by the transmitting means. The position information indicating the position where the setting information to be transmitted is stored or the identification information indicating whether or not the temporary setting information is stored is stored, and the transmission means stores the position information stored in the memory. Alternatively, according to the identification information, if the temporary setting information is stored in the memory, the temporary setting information is transmitted, and if the temporary setting information is not stored, the normal setting information is transmitted. It is characterized by.

The invention according to claim 2 is the electronic information storage medium according to claim 1, wherein the memory includes a volatile memory and a non-volatile memory, and the production means is the normal time. The setting information is stored in the non-volatile memory, and the temporary setting information is stored in the volatile memory.

The invention according to claim 3 is an IC card having a memory for storing application information related to an application and capable of communicating with a terminal device via a relay device, and the relay device is the terminal device based on the application information. The creation means includes a creation means for creating setting information used for communication setting with and storing the setting information in the memory, and a transmission means for transmitting the setting information to the relay device at a predetermined timing. The creation means is the application information. When there is an instruction to temporarily change the information, temporary setting information, which is the temporary setting information, is created based on the application information to which the temporary change has been made, and the temporary change is made. It is stored in the memory separately from the normal setting information which is the normal setting information created based on the previous application information, and the memory stores the setting information to be transmitted by the transmitting means. The position information indicating the position or the identification information indicating whether or not the temporary setting information is stored is stored, and the transmitting means stores the position information or the identification information stored in the memory in the memory. When the temporary setting information is stored, the temporary setting information is transmitted, and when the temporary setting information is not stored, the normal setting information is transmitted.

The invention according to claim 4 is a method of transmitting setting information by an electronic information storage medium having a memory for storing application information related to an application and capable of communicating with a terminal device via a relay device, based on the application information. The relay device includes a creation step of creating setting information used for communication setting with the terminal device and storing it in the memory, and a transmission step of transmitting the setting information to the relay device at a predetermined timing. In the creation step, when a temporary change instruction is given to the application information, temporary setting information which is the temporary setting information is created based on the application information to which the temporary change is added, and the temporary setting information is created. It should be stored in the memory separately from the normal setting information which is the normal setting information created based on the application information before the temporary change is made, and the memory should transmit in the transmission step. The storage step of storing the position information indicating the position where the setting information is stored or the identification information indicating whether or not the temporary setting information is stored is further included, and in the transmission step, the memory stores. According to the position information or the identification information, if the temporary setting information is stored in the memory, the temporary setting information is transmitted, and if the temporary setting information is not stored, the normal setting information is transmitted. It is characterized by doing.

The invention according to claim 5 comprises a computer included in an electronic information storage medium having a memory for storing application information related to an application and capable of communicating with a terminal device via a relay device, based on the application information. Is a setting information transmission program that functions as a creation means for creating setting information used for communication setting with the terminal device and storing it in the memory, and a transmission means for transmitting the setting information to the relay device at a predetermined timing. When the creating means is instructed to temporarily change the application information, the creating means creates temporary setting information which is the temporary setting information based on the application information to which the temporary change is added. Then, the memory is stored separately from the normal setting information, which is the normal setting information created based on the application information before the temporary change is made, and the memory is stored by the transmitting means. The position information indicating the position where the setting information to be transmitted is stored or the identification information indicating whether or not the temporary setting information is stored is stored, and the transmission means stores the position information stored in the memory. Alternatively, according to the identification information, if the temporary setting information is stored in the memory, the temporary setting information is transmitted, and if the temporary setting information is not stored, the normal setting information is transmitted. It is characterized by.

According to the present invention, even when the application information is temporarily changed and the temporary setting information is created and transmitted to the relay device, the normal setting information created based on the application information before the change is temporarily changed. Since it is stored in the memory separately from the setting information, the normal setting information can be immediately transmitted to the relay device, the communication setting is immediately made between the relay device and the terminal device, and the communication with the terminal device is performed. There is no delay in starting.

It is a figure which shows the structural example of the electronic information storage medium 100. It is a figure which shows the configuration example of the mobile terminal 1. It is a figure which shows the configuration example of a UIM card 18. It is a flowchart which shows an example of the change request processing by CPU181. It is a flowchart which shows an example of the power-on processing by CPU181.

A mode for carrying out the present invention will be described with reference to FIG.

As shown in FIG. 1, the electronic information storage medium 100 includes a memory M, an input reception unit 103, an application information management unit 104, a setting information creation unit 105, a read source identification information management unit 106, and a transmission unit 107. The memory M includes a volatile memory 101 and a non-volatile memory 102. The electronic information storage medium 100 is connected to the relay device 110 and can communicate with the terminal device 120 via the relay device 110.

The non-volatile memory 102 stores application information about the application. Further, the non-volatile memory 102 stores the normal setting information which is the normal setting information.

The volatile memory 101 stores temporary setting information which is temporary setting information. Further, the volatile memory 101 temporarily stores at least a part of the application information.

The input receiving unit 103 receives a temporary change instruction or a permanent change instruction by the user regarding application information (for example, information indicating priority between applications).

When the application information management unit 104 receives an instruction to temporarily change the application information, the application information management unit 104 temporarily changes the application information according to the content of the instruction.

When the application information management unit 104 makes a temporary change in the application information, the application information before the change on the non-volatile memory 102 may be duplicated in the volatile memory 101, and the copied application information may be changed. .. As a result, the non-volatile memory 102 holds the application information before the change (that is, at the normal time), and the volatile memory 101 holds the application information reflecting the contents of the temporary change. It becomes. Alternatively, when the application information is temporarily changed, the application information before the change may be duplicated in the non-volatile memory 102, and the copied application information may be changed. As a result, the non-volatile memory 102 holds the application information before the change (that is, at the normal time) and the application information reflecting the content of the temporary change.

Further, when the application information management unit 104 receives an instruction to permanently change the application information, the application information management unit 104 makes a permanent change to the application information stored in the non-volatile memory 102 according to the content of the instruction.

The setting information creation unit 105 creates the setting information at the normal time based on the application stored in the non-volatile memory 102. Further, when the setting information creation unit 105 stores the application information in which the contents of the change are temporarily reflected by the application information management unit 104 in the memory M (volatile memory 101 or non-volatile memory 102), the setting information creation unit 105 may store the application information in the memory M (volatile memory 101 or non-volatile memory 102). Based on the application information that reflects the content of the temporary change, temporary setting information that is temporary setting information is created and stored in the memory M (volatile memory 101 or non-volatile memory 102).

The reading source identification information management unit 106 manages the reading source identification information. The read source identification information is stored in the memory M (volatile memory 101 or non-volatile memory 102). The read source identification information is information indicating a position where the setting information to be transmitted by the transmission unit 107 is stored, and the type and address of the memory in which the normal setting information or the temporary setting information is stored are set. .. For example, when the temporary setting information is stored in the volatile memory 101, the read source identification information management unit 106 sets an address in which the temporary setting information on the volatile memory 101 is stored, and temporarily sets the information. Is stored in the non-volatile memory 102, the address in which the temporary setting information on the non-volatile memory 102 is stored is set. On the other hand, when the temporary setting information is not stored in either the volatile memory 101 or the non-volatile memory 102, the address in which the normal setting information is stored in the non-volatile memory 102 is set.

Further, when the predetermined condition is satisfied, the read source identification information management unit 106 sets the read source identification information as an address in which the normal setting information on the non-volatile memory 102 is stored. The predetermined condition referred to here is, for example, after the power supply to the electronic information storage medium 100 is cut off (for example, the voltage at the power supply terminal becomes less than the predetermined voltage) and the information on the volatile memory 101 is erased. , The power supply to the electronic information storage medium 100 is restarted (for example, the voltage at the power supply terminal becomes equal to or higher than a predetermined voltage), the non-contact interface is reset, and the like.

The transmission unit 107 transmits the normal setting information or the temporary setting information stored in the position indicated by the reading source identification information to the relay device. For example, the transmission unit 107 transmits the normal setting information or the temporary setting information when it detects that the content of the reading source identification information has been updated.

Next, an operation example of the electronic information storage medium 100 will be described. First, the input receiving unit 103 receives an input requesting from the user to temporarily preferentially select a specific application among a plurality of applications mounted on the electronic information storage medium 100. Next, the application information management unit 104 copies the application information stored in the non-volatile memory 102 to the volatile memory 101, and changes the application information according to the request. Next, the setting information creation unit 105 creates temporary setting information based on the application information that has been temporarily changed on the volatile memory 101, and stores it in the volatile memory 101. Next, the read source identification information management unit 106 sets an address in which the temporary setting information on the volatile memory 101 is stored as the read source identification information. Next, the transmission unit 107 transmits the temporary setting information stored in the address indicated by the reading source identification information to the relay device 110. Then, after an initial response is made between the relay device 110 and the terminal device 120 and communication (communication with the contents temporarily changed) is performed between the electronic information storage medium 100 and the terminal device 120, When the power supply to the electronic information storage medium 100 is cut off and the power supply to the electronic information storage medium 100 is restarted again, the read source identification information management unit 106 displays the read source identification information on the non-volatile memory 102. Set the address where the normal setting information of is stored. Next, the transmission unit 107 transmits the normal setting information stored in the address indicated by the reading source identification information to the relay device 110. After that, an initial response is made between the relay device 110 and the terminal device 120 based on the setting information in the normal state, and communication (before a temporary change is made) between the electronic information storage medium 100 and the terminal device 120. (Communication with the contents of (normal contents)) is performed.

That is, the electronic information storage medium 100 is an electronic information storage medium that includes a memory M for storing application information related to the application and can communicate with the terminal device 120 via the relay device 110, and is a setting information creation unit 105 (“creation”). An example of the "means") creates setting information used by the relay device 110 for communication settings with the terminal device 120 based on the application information, stores the setting information in the memory M, and the transmission unit 107 (an example of the "transmission means"). The setting information is transmitted to the relay device at a predetermined timing, and when the setting information creation unit 105 is instructed to temporarily change the application information, the setting information creation unit 105 temporarily changes the application information based on the temporarily changed application information. Temporary setting information that is typical setting information is created, and is stored in the memory M separately from the normal setting information that is the normal setting information created based on the application information before the temporary change is made. When the temporary setting information is stored in the memory M, the transmission unit 107 transmits the temporary setting information, and when the temporary setting information is not stored, the transmission unit 107 transmits the normal setting information.

Therefore, according to the electronic information storage medium 100, even when the application information is temporarily changed and the temporary setting information is created and transmitted to the relay device 110, the application information is created based on the application information before the change. Since the normal setting information is stored in the memory separately from the temporary setting information, the normal setting information can be immediately transmitted to the relay device 110, and the communication setting between the relay device 110 and the terminal device 120 can be set. It is done immediately and there is no delay in starting communication with the terminal device.

Next, a specific example corresponding to the above-described embodiment will be described. The examples described below are examples in which the present invention is applied to an IC chip mounted on a UIM card provided in a mobile terminal.

First, the configuration and functional outline of the mobile terminal 1 according to this embodiment will be described with reference to FIG. 2 and the like.

[1. Configuration of mobile terminal 1]
FIG. 2 is a block diagram showing a schematic configuration example of the mobile terminal 1 according to the present embodiment. As shown in FIG. 2, the mobile terminal 1 includes a control unit 11, a storage unit 12, a wireless communication unit 13, a display unit 14, an input unit 15, a CLF interface 16a, an IC card interface 16b, a CLF (Contactless frontend) 19, and the like. These components are connected to each other via the bus 17. Further, the mobile terminal 1 includes a battery B and a UIM card 18. The mobile terminal 1 is, for example, a mobile phone, a smartphone, a tablet terminal, or the like.

The control unit 11 is composed of a CPU (Central Processing Unit), a ROM (Read Only Memory), a RAM (Random Access Memory), and the like. The storage unit 12 is composed of a non-volatile memory such as a flash memory. The OS (Operating System) and middleware of the mobile terminal 1 are stored in the ROM or the storage unit 12. Further, the storage unit 12 stores APIs (Application Program Interfaces) and applications (hereinafter, may be referred to as “applications”) installed in the mobile terminal 1. The API is an interface for using the functions of the operating system from the application. An application is, for example, a program that can be downloaded from a predetermined server.

The wireless communication unit 13 has an antenna and controls wireless communication performed with a base station in the mobile communication network. The display unit 14 has, for example, a touch panel type display panel, and controls the display on the display panel and receives operation instructions from the user. The input unit 15 has an operation button for inputting an operation instruction from the user, and outputs a signal corresponding to the operation button to the control unit 11. The CLF interface 16a serves as an interface between the control unit 11 and the CLF 19, and the IC card interface 16b serves as an interface between the control unit 11 and the UIM (User Identity Module) card 18.

The UIM card 18 is one of the UICCs (Universal Integrated Circuit Cards), which is an IC card. For example, the UIM card 18 is equipped with a contact type IC chip whose functions are expanded based on the conventional SIM (Subscriber Identity Module).

CLF19 is a non-contact IC chip that performs non-contact communication specified by the NFC (Near Field Communication) standard, and has various types of non-contact R / W (not shown) in the field of non-contact communication. It is connected to an antenna for transmitting and receiving signals. Then, when the user holds the mobile terminal 1 over the non-contact R / W, an initial response is performed with the non-contact R / W based on the setting information of the UIM card 18 held in advance. Then, when the initial response is properly completed, the CLF 19 transmits the command transmitted from the non-contact R / W to the UIM card 18 via the interface (not shown), and responds to the command transmitted from the UIM card 18. The response is returned to the non-contact R / W. The CLF 19 can be operated by the OS of the mobile terminal 1.

The battery B is composed of, for example, a lithium ion battery. The control unit 11, the storage unit 12, the wireless communication unit 13, the display unit 14, the input unit 15, the CLF interface 16a, the IC card interface 16b, the CLF 19 and the like operate according to the power supplied from the battery B. The battery B can supply power to the UIM card 18 even when the power of the mobile terminal 1 is OFF (however, when the voltage of the battery B becomes equal to or lower than the specified voltage, the battery B is supplied by the function of the safety protection circuit ( Discharge) is cut off).

[2. Configuration of IC chip C]
FIG. 3 is a block diagram showing a schematic configuration example of the IC chip C mounted on the UIM card 18 according to the present embodiment. As shown in FIG. 3, the IC chip C includes a CPU 181 and a RAM 182, a flash memory 183, an I / O circuit 184, and the like, and these components are connected to each other via a bus 185.

The RAM 182 stores, for example, data temporarily required for the OS of the IC chip C, middleware, and various applications to function. In addition, temporary temporary setting information and a priority list showing the priority of the application are stored.

The flash memory 183 is a non-volatile memory, and for example, "Electrically Erasable Programmable Read-Only Memory" may be adopted instead. For example, the OS of the IC chip C, middleware, and various applications are stored in the flash memory 183.

Further, the flash memory 183 stores data (programs, instances, various information) related to the application installed on the UIM card 18 (IC chip C). The app is implemented as a software program that runs on Java® Card. In the flash memory of this embodiment, the priority of the credit card payment applications of companies A, B, and C, and the user temporarily or permanently changes the priority among the credit card payment applications, and the availability of the flash memory is changed. An input app (for example, CRS applet) is installed to change the protocol data of the app. The input is accepted as a command word (command EPADU (Application Protocol Data Unit)) via the contact interface.

Further, the flash memory 183 stores normal setting information, a priority list indicating the priority of the application, a availability list indicating the availability of the application, and reading source identification information.

In the priority list of the flash memory 183, information indicating the priority of the credit card payment application in the normal time is described. On the other hand, the priority list of the RAM 182 describes information indicating the priority of the credit payment application when the priority of the credit payment application is temporarily changed by the user. When the user makes a credit payment, if the mobile terminal 1 is held over the non-contact R / W, the payment is made by the credit card payment application having the highest priority. Therefore, the user sets the priority of the credit card payment application that is normally used to be the highest, and when temporarily making a payment by another credit card payment application, the input application is used for the other. It can be set so that the priority of the credit card payment application is the highest. Then, when the payment by another credit card payment application is temporarily completed and then the credit card payment application is used, the priority of the credit card payment application normally used is set unless a temporary change is made. It has become the highest, and payment by the credit card payment application is possible.

The normal setting information stored in the flash memory 183 is based on the contents of the priority list stored in the flash memory 183, the contents of the availability list, the bit rate of TYPE A [ISO-14443-3], and the like. Is created. However, it may include the collision avoidance response of TYPE F, which is another parameter of TYPE A / TYPE B. On the other hand, the temporary setting information stored in the RAM 182 is basically created based on the same information as the normal setting information, but the priority list is based on the contents of the priority list stored in the RAM 182.

The I / O circuit 184 has eight connection terminals C1 to C8 defined by ISO7816 and the like. For example, the C1 terminal is a power supply terminal, the C2 terminal is a reset terminal, the C3 terminal is a clock terminal, the C5 terminal is a ground terminal, and the C7 terminal is a terminal for data communication with the mobile terminal 1. A line that receives power from CLF 19 is connected to the C1 terminal. The electric power from the battery B and the electric power from the carrier wave from the non-contact R / W are input to the CLF 19 and supplied to the IC chip C. However, if there is power supply from both sides, the power from the battery B has priority. The switching from the power supply of the battery B to the power supply by the carrier wave is performed after the supply voltage to the IC chip is OFF.

The I / O circuit 184 provides a contact interface and a non-contact interface. The contact interface is implemented as a UART (Universal Asynchronous Receiver Transmitter) that supports T = 0 [ISO-7816]. The non-contact interface is implemented as a SWP (Single Wire Protocol) [ETSI 102.613] that supports the HCI (Host Controller Interface) [ETSI (European Telecommunications Standards Institute) 102.622].

When the CPU 181 receives a command from the CLF 19, the CPU 181 executes a command correspondence process corresponding to the command and responds to the CLF 19 (specifically, sends response data including the result of the command correspondence process to the CLF 19). When the CPU 181 receives a command from the control unit 11, the CPU 181 executes a command correspondence process corresponding to the command and responds to the control unit 11 (specifically, controls data indicating the result of the command correspondence process). It is transmitted to the part 11.

Further, as a function of the OS, when the CPU 181 receives a request to temporarily change the priority list via the input application, the CPU 181 copies the priority list of the flash memory 183 to the RAM 182 and makes the change according to the request. Do. Next, as a function of the OS, the CPU 181 creates temporary setting information that reflects the contents of the priority list stored in the RAM 182, stores the temporary setting information in the RAM 182, and sets the storage destination address in the read source identification information.

On the other hand, when the CPU 181 receives a request to permanently change the priority list or the availability list via the input application as a function of the OS, the contents of the priority list or the availability list stored in the flash memory 183. Is changed on demand. Next, as a function of the OS, the CPU 181 creates normal setting information that reflects the contents of the priority list or the availability list stored in the flash memory 183, stores the setting information in the flash memory 183, and stores the address of the storage destination. Is set as the reading source identification information.

Further, as a function of the OS, the CPU 181 sets the address of the normal setting information on the flash memory 183 as the read source identification information when the voltage of the power supply terminal becomes a voltage of a constant value from the voltage level of the ground terminal. To do. For example, when the user of the mobile terminal 1 turns off the power of the mobile terminal 1, the power supply from the battery B is cut off, the voltage of the power supply terminal drops to the voltage level of the ground terminal, and then the power supply by the carrier is performed. When the voltage of the power supply terminal reaches a constant value, the address of the normal setting information on the flash memory 183 is set in the read source identification information.

Furthermore, when the read source identification information is updated, the CPU 181 transmits the temporary setting information or the normal setting information stored in the address indicated by the read source identification information to the CLF 19 via the non-contact interface. Specifically, it is implemented as a driver that processes the HCI protocol layer, and the transmission processing of setting information is performed as a part of the initialization processing of PIPE, which is a logical channel of the HCI layer.

[3. Operation of IC chip C]
Next, an operation example of the IC chip C will be described with reference to FIGS. 4 and 5. FIG. 4 is a flowchart showing an operation example of the change request processing when a request for changing the priority list is received by the input application, and FIG. 5 is a flowchart when the power is turned on when the power is turned on to the IC chip C. It is a flowchart which shows the operation example of a process.

As shown in FIG. 4, in the change request processing, the CPU 181 first determines whether or not the request for changing the priority has been accepted via the input application (step S101). When the CPU 181 determines that the request for changing the priority is not accepted (step S101: NO), the CPU 181 ends the process shown in the flowchart. On the other hand, when the CPU 181 determines that the request for changing the priority has been accepted (step S101: YES), the CPU 181 determines whether or not the request for change is a temporary request (step S102).

When the CPU 181 determines that the change request is a temporary request (step S102: YES), the CPU 181 updates the priority list of the RAM 182 (step S103). For example, the CPU 181 copies the priority list of the flash memory 183 to the RAM 182, and changes the priority according to the request.

Next, the CPU 181 creates temporary setting information based on the priority list of the RAM 182 and information about other applications, and stores the temporary setting information in the RAM 182 (step S104).

Next, the CPU 181 sets the address in which the temporary setting information is stored in the read source identification information (step S105), and proceeds to the process of step S109.

On the other hand, when the CPU 181 determines that the change request is not a temporary request (that is, it is a permanent request) (step S102: NO), the CPU 181 updates the priority list of the flash memory 183 (step S106). ).

Next, the CPU 181 creates the normal setting information based on the priority list of the flash memory 183 and the information about other applications, and stores it in the flash memory 183 (step S107).

Next, the CPU 181 sets the address in which the normal setting information is stored in the read source identification information (step S108), and proceeds to the process of step S109.

Next, the CPU 181 confirms the state of the non-contact interface (step S109). Specifically, the CPU 181 operates as a driver for managing the HCI session, and confirms whether a PIPE for communicating with the non-contact R / W has been established. If it has already been opened, check whether communication is being executed on PIPE.

Next, the CPU 181 determines whether or not the PIPE initialization process is possible as a result of checking the state of the non-contact interface (step S110). Specifically, the CPU 181 determines that the PIPE initialization process is impossible when the PIPE is not opened, or when the PIPE is already opened but communication is in progress. When the CPU 181 determines that the PIPE initialization process is impossible (step S110: NO), the CPU 181 ends the process shown in the flowchart. As a result of checking the state of the non-contact interface, the CPU 181 determines that the non-contact interface cannot be used (when SWP communication is not established, including the case where it is not electrically connected), in the process of step S110. It is determined as "NO". On the other hand, when the CPU 181 determines that the PIPE initialization process is possible (step S110: YES), the CPU 181 then performs the PIPE initialization process (step S111), and ends the process shown in the flowchart. In the initialization process of PIPE, the CPU 181 transmits the temporary setting information on the RAM 182 or the normal setting information on the flash memory 183 stored at the address indicated by the read source designation information to the CLF 19.

Next, an operation example of the power-on processing will be described with reference to FIG.

As shown in FIG. 5, in the power-on processing, the CPU 181 first determines whether or not the power is turned on (step S201). For example, when the voltage of the power supply terminal reaches a certain value or more, it is determined that the power is turned on. When the CPU 181 determines that the power is not turned on (step S201: NO), the CPU 181 ends the process shown in the flowchart. On the other hand, when the CPU 181 determines that the power is turned on (step S201: YES), the CPU 181 determines whether or not the address in which the temporary setting information is stored (that is, the address on the RAM 182) is set in the read source identification information. (Step S202).

When the CPU 181 determines that the address in which the temporary setting information is stored is not set in the read source identification information (step S202: NO), the CPU 181 ends the process shown in the flowchart. On the other hand, when the CPU 181 determines that the address in which the temporary setting information is stored is set in the reading source identification information (step S202: YES), then the normal setting information is stored in the reading source identification information. (That is, the address where the normal setting information on the flash memory 183 is stored) is set (step S203).

Next, the CPU 181 confirms the state of the non-contact interface (step S204). Specifically, the CPU 181 confirms whether PIPE has already been opened.

Next, the CPU 181 determines whether or not the PIPE initialization process is possible as a result of checking the state of the non-contact interface (step S205). When the CPU 181 determines that the PIPE initialization process is impossible (step S205: NO), the CPU 181 ends the process shown in the flowchart. As a result of checking the state of the non-contact interface, the CPU 181 determines that the non-contact interface cannot be used (when SWP communication is not established, including the case where it is not electrically connected), in the process of step S205. It is determined as "NO". On the other hand, when the CPU 181 determines that the PIPE initialization process is possible (step S205: YES), the CPU 181 then performs the PIPE initialization process (step S206), and ends the process shown in the flowchart. In the initialization process of PIPE, the CPU 181 transmits the normal setting information on the flash memory 183 stored at the address indicated by the read source designation information to the CLF 19.

As described above, according to the above embodiment, the IC chip C (an example of an "electronic information storage medium") includes a flash memory 183 for storing application information related to an application, and is a CLF 19 (an example of a "relay device"). It is possible to communicate with a non-contact R / W (an example of a "terminal device"), and the CPU 181 (an example of a "creating means" and a "transmitting means") can be used for application information including contents such as a priority list. Based on this, the CLF 19 creates setting information for performing an initial response with the non-contact R / W, stores it in the flash memory 183, and when the power is turned on (an example of "predetermined timing"), the normal setting information is stored. Send to CLF19. Further, when the CPU 181 is instructed to temporarily change the application information such as the priority list, the CPU 181 performs temporary setting information which is temporary setting information based on the application information to which the temporary change is added. Created and stored in the RAM 182 separately from the normal setting information, the temporary setting information is transmitted when the temporary setting information is stored in the RAM 182, and the temporary setting information is not stored in the RAM 182. The normal setting information of the flash memory 183 is transmitted.

Therefore, according to the IC chip C, even if the application information is temporarily changed and the temporary setting information is created and transmitted to the CLF 19, the normal setting information created based on the application information before the change is used. Is stored in the flash memory 183 separately from the temporary setting information, so that the normal setting information can be immediately transmitted to the CLF 19, and an initial response is immediately made between the CLF 19 and the non-contact R / W, which is not possible. There is no delay in starting communication with the contact R / W.

Further, the flash memory 183 stores the reading source identification information (an example of "position information") indicating the position where the setting information to be transmitted to the CLF 19 is stored, and the CPU 181 stores the setting information or the setting information according to the reading source identification information. Send temporary setting information. Therefore, when the setting information is transmitted to the CLF 19, the position where the setting information is stored can be instantly grasped, and the time until the setting information is transmitted to the CLF 19 can be shortened.

It should be noted that the setting information is stored in advance at a predetermined position on the flash memory 183 and the temporary setting information is stored at a predetermined position on the RAM 182. When the CPU 181 transmits the setting information to the CLF 19, the setting information is stored on the RAM 182. When the temporary setting information is stored in the predetermined position, the temporary setting information is transmitted, while when the temporary setting information is not stored in the predetermined position on the RAM 182, it is stored in the predetermined position on the flash memory 183. The setting information that has been set may be transmitted. In this case, it is possible to reduce the processing load of updating the reading source identification information. In addition to this, the flash memory 183 stores the temporary setting information presence / absence information instead of the read source identification information, and when the CPU 181 stores the temporary setting information at a predetermined position on the RAM 182, the temporary setting information presence / absence is stored. If the information indicating "Yes" is set in the information and the temporary setting information is not stored, the information indicating "No" is set in the temporary setting information presence / absence information, and when the setting information is transmitted, the information indicating "No" is set. When the information indicating "Yes" is set in the temporary setting information presence / absence information, the temporary setting information stored in the predetermined position on the RAM 182 is transmitted, and the information indicating "No" in the temporary setting information presence / absence information. If is set, the normal setting information stored in a predetermined position on the flash memory 183 may be transmitted.

In the above embodiment, the IC chip C has been described as an example of the electronic information storage medium of the present invention, but the present invention can also be applied to an embedded microchip or the like.

100 Electronic information storage medium M memory 101 Volatile memory 102 Non-volatile memory 103 Input reception unit 104 App information management unit 105 Setting information creation unit 106 Read source identification information management unit 107 Transmission unit 110 Relay device 120 Terminal device 1 Mobile terminal 11 Control Unit 12 Storage unit 13 Wireless communication unit 14 Display unit 15 Input unit 16a CLF interface 16b IC card interface 17 Bus 18 UIM card C IC chip 181 CPU
182 RAM
183 Flash memory 184 I / O circuit 19 CLF
B battery

Claims (5)

An electronic information storage medium that has a memory for storing application information related to an application and can communicate with a terminal device via a relay device.
A creation means for creating setting information used by the relay device for communication setting with the terminal device based on the application information and storing it in the memory.
A transmission means for transmitting the setting information to the relay device at a predetermined timing, and
With
When there is an instruction to temporarily change the application information, the creating means creates temporary setting information which is the temporary setting information based on the application information to which the temporary change is added. It is stored in the memory separately from the normal setting information which is the normal setting information created based on the application information before the temporary change is made.
The memory stores position information indicating a position where the setting information to be transmitted by the transmission means is stored, or identification information indicating whether or not the temporary setting information is stored.
The transmission means transmits the temporary setting information when the temporary setting information is stored in the memory according to the position information or the identification information stored in the memory, and the temporary setting information is stored. An electronic information storage medium characterized in that the normal setting information is transmitted when there is no such information. The electronic information storage medium according to claim 1.
The memory is configured to include a volatile memory and a non-volatile memory.
The creating means is an electronic information storage medium characterized in that the normal setting information is stored in the non-volatile memory and the temporary setting information is stored in the volatile memory. An IC card that has a memory for storing application information related to an application and can communicate with a terminal device via a relay device.
A creation means for creating setting information used by the relay device for communication setting with the terminal device based on the application information and storing it in the memory.
A transmission means for transmitting the setting information to the relay device at a predetermined timing, and
With
When there is an instruction to temporarily change the application information, the creating means creates temporary setting information which is the temporary setting information based on the application information to which the temporary change is added. It is stored in the memory separately from the normal setting information which is the normal setting information created based on the application information before the temporary change is made.
The memory stores position information indicating a position where the setting information to be transmitted by the transmission means is stored, or identification information indicating whether or not the temporary setting information is stored.
The transmission means transmits the temporary setting information when the temporary setting information is stored in the memory according to the position information or the identification information stored in the memory, and the temporary setting information is stored. If not, the IC card is characterized by transmitting the normal setting information. It is a setting information transmission method using an electronic information storage medium that has a memory for storing application information related to an application and can communicate with a terminal device via a relay device.
A creation step of creating setting information used by the relay device for communication setting with the terminal device based on the application information and storing it in the memory.
A transmission step of transmitting the setting information to the relay device at a predetermined timing, and
Including
In the creation step, when a temporary change instruction is given to the application information, temporary setting information which is the temporary setting information is created based on the application information to which the temporary change is added. It is stored in the memory separately from the normal setting information which is the normal setting information created based on the application information before the temporary change is made.
The memory further includes a storage step of storing position information indicating a position where setting information to be transmitted in the transmission step is stored, or identification information indicating whether or not the temporary setting information is stored.
In the transmission step, when the temporary setting information is stored in the memory, the temporary setting information is transmitted according to the position information or the identification information stored in the memory, and the temporary setting information is stored. A method for transmitting setting information, which comprises transmitting the normal setting information when there is no such information. A computer included in an electronic information storage medium that has a memory for storing application information related to an application and can communicate with a terminal device via a relay device.
A creating means for creating setting information used by the relay device for communication setting with the terminal device based on the application information and storing it in the memory.
A transmission means for transmitting the setting information to the relay device at a predetermined timing.
It is a setting information transmission program that functions as
When there is an instruction to temporarily change the application information, the creating means creates temporary setting information which is the temporary setting information based on the application information to which the temporary change is added. It is stored in the memory separately from the normal setting information which is the normal setting information created based on the application information before the temporary change is made.
The memory stores position information indicating a position where the setting information to be transmitted by the transmission means is stored, or identification information indicating whether or not the temporary setting information is stored.
The transmission means transmits the temporary setting information when the temporary setting information is stored in the memory according to the position information or the identification information stored in the memory, and the temporary setting information is stored. A setting information transmission program characterized by transmitting the normal setting information when there is no such information.

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