JP2012043305A - Terminal device, data reading method, data reading program and the like - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a terminal device, a data reading method, a data reading program and the like which surely read and register data from data reading objects.SOLUTION: When reading identification information, from a RFID tag existing in a first communication range, a CPU of a portable phone 1 reads identification information stored in the RFID tag, and when registering identification information, from a RFID tag existing in a second communication range smaller than the first communication range, the CPU reads identification information stored in the RFID tag.

Description

  The present invention relates to a terminal device, a data reading method, a data reading program, and the like, and more specifically, for example, a terminal device, a data reading method, and a data reading program that reliably read and register data from a data reading target. Related to the technical field.

  In recent years, in a mobile phone having an IC tag (for example, RFID tag) reader function, by reading and registering data stored in the RFID tag (for example, identification information, URL address, or discount coupon information such as a product), It is used for various purposes (for example, specifying the RFID tag, accessing a URL address, or using it as a discount ticket when purchasing a product).

  However, since the mobile phone transmits a request to read data stored in the RFID tag to all RFID tags that exist within the communication range in which data communication is possible, only the RFID tag that is the target of data reading is transmitted. In addition, there is a possibility that data is read even from an RFID tag that is not symmetrical with respect to data reading.

  Therefore, the present invention has been made in view of the above problems, and an example of the object is to provide a terminal device, a data reading method, a data reading program, and the like that reliably read data from a data reading target. And

  In order to solve the above problem, the invention described in claim 1 is a terminal device that reads and registers data stored in an RFID tag by a non-contact communication method within a communication range in which data communication is possible. The first communication means for reading the identification information stored in the RFID tag from the RFID tag existing in the first communication range at the time of reading, and narrower than the first communication range at the time of registration A second communication means for reading identification information stored in the RFID tag from an RFID tag existing in the second communication range; a registration means for registering identification information read by the second communication means; Communication control means for switching between the first communication means and the second communication means.

  Therefore, the data is reliably read and registered from the data reading target.

  Invention of Claim 2 is a terminal device of Claim 1, Comprising: The said 2nd communication means WHEREIN: The electric field strength in the said 2nd reading range is set to the electric field strength in the 1st reading range. Rather than a weaker electric field strength.

  Therefore, data is read and registered more reliably from the data reading target.

A third aspect of the present invention is the terminal device according to the first aspect, wherein the first communication means defines a communication standard that enables data communication with a specific RFID tag. According to the communication standard, the RFID tag identification information stored in the RFID tag corresponding to the first communication standard is read, and the second communication means communicates data with a specific RFID tag. In accordance with the second communication standard that defines the communication standard to be enabled, the RFID tag identification information corresponding to the first communication standard stored in the RFID tag corresponding to the second communication standard is read.
Therefore, the data is read and registered more reliably from the data reading target.

  According to a fourth aspect of the present invention, there is provided a data reading method in a terminal device that performs reading and registration of data stored in an RFID tag by a non-contact communication method within a communication range in which data communication is possible. Sometimes a first communication step for reading identification information stored in the RFID tag from an RFID tag existing in the first communication range, and a second time narrower than that in the first communication range at the time of registration. A second communication step of reading identification information stored in the RFID tag from an RFID tag existing within a communication range; a registration step of registering identification information read by the second communication means; And a communication control step for switching the second communication means.

  According to the fifth aspect of the present invention, a computer included in a terminal device that performs reading and registration of data stored in an RFID tag in a non-contact communication method within a communication range in which data communication is possible, First communication means for reading identification information stored in the RFID tag from an RFID tag existing in the first communication range, and at the time of registration, in a second communication range narrower than the first communication range The second communication means for reading the identification information stored in the RFID tag from the RFID tag present in the RFID tag, the registration means for registering the identification information read by the second communication means, the first communication means and the It functions as a communication control means for switching the second communication means.

  As described above, according to the present invention, when registering data stored in an RFID tag, the terminal device reads and registers the identification information stored in the RFID tag from the RFID tag that exists within a narrow communication range. Therefore, data can be reliably read from the RFID tag.

It is a block diagram which shows an example of the whole structure of the security lock system which concerns on this embodiment. 3 is a conceptual diagram showing an example of functional blocks in the mobile phone 1. FIG. It is a state chart figure which shows operation | movement of CPU of the mobile telephone 1 in 1st Embodiment. It is a conceptual diagram which shows the range which CPU of the mobile telephone 1 in 1st Embodiment reads the identification information of a RFID tag. It is a state chart figure which shows operation | movement of CPU of the mobile telephone 1 in 2nd Embodiment. It is a conceptual diagram which shows the range which CPU of the mobile telephone 1 in 2nd Embodiment reads the identification information of an RFID tag.

  DESCRIPTION OF EXEMPLARY EMBODIMENTS Hereinafter, the best mode for carrying out the invention will be described with reference to the drawings. In addition, embodiment described below is embodiment at the time of applying this application with respect to the security lock system in a mobile telephone (an example of a terminal device).

[1. Configuration and function of security lock system]
First, the configuration and function of the security lock system according to the present embodiment will be described with reference to FIG.

  Here, the configuration and the outline of the operation of the security lock system described below are, for example, that a mobile phone having an IC tag (RFID tag) reader function is affixed to an article carried by a mobile phone user existing within a communication range. This is an embodiment in which the present application is applied to a security lock system that collates identification information read from an RFID tag and identification information registered in the mobile phone in advance and releases the security lock if they match. .

  The security lock is a well-known technique and will not be described in detail. However, in order to prevent a person other than the user of the mobile phone from operating the mobile phone, , Key operations, etc.) for locking (invalidating). Then, based on a user operation or when no key operation is performed for a certain period of time, the security lock is executed under the control of a program (security lock dedicated application described later) stored in the mobile phone.

  That is, in the security lock system, when a predetermined number of articles (RFID tags are attached) carried by the user of the mobile phone exist around the mobile phone, the user exists around the mobile phone. It is assumed that the user carrying the predetermined article is holding the mobile phone, and the security lock is released (terminated).

  FIG. 1 is a block diagram showing an example of the overall configuration of the security lock system according to the present embodiment.

  As shown in FIG. 1, the security lock system S includes an RFID tag 2A on each of a mobile phone 1 (an example of a terminal device of the present application), a wallet 2, a notebook 3, and a wristwatch 4 as articles carried by the user of the mobile phone. 3A and 4A are attached.

  The mobile phone 1 and the RFID tags 2A, 3A, and 4A can read and write data mutually by a reader / writer function provided in the mobile phone 1, as will be described in detail later.

  In the example of FIG. 1, for convenience of explanation, three articles (the wallet 2, the notebook 3, and the wristwatch 4) carried by the user of the mobile phone are shown, but the present invention is not limited to this. Further, a large number of mobile phones 1 may exist for each user.

[1-1. Configuration and function of mobile phone 1]
The cellular phone 1 includes an antenna, a speaker, a microphone, operation keys, a display, a CPU (an example of a first communication unit, a second communication unit, and a communication control unit in the present embodiment), a RAM, and a ROM (various data). And a program that records the operation of the mobile phone 1 in advance), and a control device that includes a storage unit (an example of storage means of the present application) and the like.

  FIG. 2 is a conceptual diagram showing an example of functional blocks in the mobile phone 1.

  As shown in FIG. 2, the mobile phone 1 has a general external communication control function (for example, according to a W-CDMA or CDMA2000 communication method), a browser function (a URL is specified to access a predetermined server, and (For example, by http (Hyper Text Transfer Protocol)), a mailer function (for example, using the mailer as a user interface, data is transmitted / received to / from other mobile phones or servers via a network. ), A mobile application (software that directly has a function of performing an operation that a user of the mobile phone wants to perform on the mobile phone) and the like. In addition, since these functions in the mobile phone 1 are publicly known, detailed description is omitted.

  The cellular phone 1 according to the present embodiment includes an antenna, a communication control unit (an example of a communication control unit in the present embodiment), and the like, and enables data communication with the RFID tags 2A, 3A, and 4A described above. It has a reader / writer function.

  This reader / writer function performs power transmission necessary for driving an RFID tag and data transmission according to a predetermined communication standard (for example, data transmission) within a communication range in which data communication is possible. A signal requesting a reply (transmitting an identification information transmission request signal, which will be described later) is performed, and data transmitted from the RFID tag is read by a non-contact communication method (by a wireless communication method).

  This communication range indicates a distance in which the data can be communicated between the mobile phone 1 and the RFID tag, and is determined according to the communication standard. Specifically, the communication range is several cm to 1.0 m in ISO / IEC 18000-2 (135 KHz or less wireless communication system), and the communication range is several in ISO / IEC 18000-3 (13.56 MHz wireless communication system). cm to several tens of centimeters, the communication range is up to 10 m for ISO / IEC18000-4 (950 MHz band wireless communication system), and the communication range is up to 2.0 m for ISO / IEC18000-5 (2.45 GHz band wireless communication system). It is stipulated.

  The CPU of the mobile phone 1 according to the present embodiment can arbitrarily switch the communication standard.

  In addition, the communication range changes according to the electric field strength of the signal transmitted from the mobile phone 1. Specifically, for example, a case is considered in which the communication control unit communicates the data with the RFID tag according to a predetermined communication standard (for example, ISO / IEC 18000-2). As described above, the communication range in the communication standard is several cm to 1.0 m. However, when the electric field strength of the signal transmitted from the mobile phone 1 is stronger, the communication range is close to 1.0 m. When the electric field strength is weak, the communication range changes to a value close to several centimeters.

  The CPU of the mobile phone 1 in this embodiment can arbitrarily change the electric field intensity.

  Since the switching of the communication standard and the change of the electric field strength are known techniques, a detailed description thereof will be omitted. (That is, signals of each frequency band defined by the standards of 135 KHz or less, 13.56 MHz, 950 MHz, and 2.45 GHz) may be generated, and a plurality of reader / writer devices corresponding to the respective frequencies may be included. You may make it comprise.

  Furthermore, the mobile phone 1 in the present embodiment has a security lock dedicated application as an example of the mobile application. This security lock dedicated application is software for realizing the security lock system described above.

  Specifically, when a key operation is not performed based on an operation of a user of the mobile phone or when a key operation is not performed for a certain period of time, a security lock dedicated application is activated, and the CPU of the mobile phone 1 controls the security lock described above under the control of the app. Execute.

  At the same time, the CPU of the mobile phone 1 reads the identification information stored in the RFID tag existing in the communication range (an example of the first communication range of the present application) via the communication control unit. A signal for requesting a reply is transmitted (that is, polling is performed).

  The CPU of the mobile phone 1 collates the identification information read from the RFID tag with the identification information registered in advance in the mobile phone, and releases the security lock if they match.

  As the mobile device, for example, a mobile phone, a PDA, a portable player, or the like can be applied. However, in this embodiment, the mobile phone 1 is applied.

[1-2. Configuration and function of RFID tag 2A]
The RFID tag 2A includes an interface including an antenna (not shown), a ROM (Read Only Memory), a RAM (Random Access Memory), an EEPROM, a CPU (Central Processing Unit), and the like. The interface is an input / output port (port) through which the above-described data and the like are transmitted and received, and the CPU communicates with the above-described mobile phone 1 and the like via the interface. The EEPROM is a kind of nonvolatile semiconductor memory, and is a PROM (Programmable Rom) that can erase data stored in a storage area and re-store it any number of times. Further, the EEPROM stores (stores) the identification information described above. This identification information is identification information for identifying the RFID tag 2A itself from other RFID tags, and is stored in advance by the RFID tag manufacturer or the like at the time of manufacture.

  In the RFID tag 2A configured as described above, when a signal requesting the return of data transmitted from the CPU of the mobile phone 1 is received, a voltage based on the signal is induced in the antenna, and the induced voltage is applied to the CPU. Supplied. When the CPU is activated by supplying power based on the voltage and receives the signal, the cellular phone 1 within the communication range receives data (for example, identification information) stored in an EEPROM or the like via the antenna. According to the communication standard.

[2. Operation of mobile phone 1 in security lock system S]
Next, operation | movement of the mobile telephone 1 in the security lock system S of this embodiment is demonstrated using FIGS.

  As described above, the identification information of the RFID tag is registered in advance in the storage unit of the mobile phone 1. The registration of the identification information is registered by the CPU of the mobile phone 1 under the control of the security lock dedicated application described above (hereinafter, the operation of registering the identification information by the control of the application is referred to as “ Registration mode ”).

  In this registration mode, the CPU of the mobile phone 1 requests the RFID tag to return the identification information (an example of the data) stored in the RFID tag (hereinafter referred to as “identification information transmission request signal”). Send). The CPU of the RFID tag that has received the identification information transmission request signal transmits the identification information to the mobile phone 1 within the communication range via the antenna. The CPU of the mobile phone 1 registers the received identification information in a storage unit (for use in the security lock system described above).

  Furthermore, the CPU of the mobile phone 1 in the present embodiment transmits the identification information transmission request signal by a different method.

  Hereinafter, the CPU of the mobile phone 1 will be described separately for the first embodiment and the second embodiment according to the method for transmitting the identification information transmission request.

A) First Embodiment First, details of the first embodiment will be described with reference to FIGS. 3 and 4.

  FIG. 3 is a state chart showing the operation of the CPU of the mobile phone 1 in the first embodiment, and FIG. 4 is a range in which the CPU of the mobile phone 1 in the first embodiment reads the identification information of the RFID tag. FIG.

  The first embodiment is a mode in which the CPU of the mobile phone 1 transmits the identification information request signal in the registration mode with an electric field strength lower than the electric field strength of the identification information request signal transmitted during execution of the security lock. is there.

  The state chart shown in FIG. 3 describes the transition of the operation state of the CPU 1 of the mobile phone 1 and includes a standby state, a registration state, a search state, and a management state.

  When there is a common action (action) when transitioning to each state, the entry / of each state, and the action continuously performed while in this state is do /, and from this state When there is a common operation when transitioning to another state, it is described in exit /.

  The CPU of the mobile phone 1 enters a standby state when the power is turned on. In this standby state, for example, when an instruction (hereinafter referred to as “interrupt event”) for executing various functions of the above-described mobile phone or the like is input, the CPU of the mobile phone 1 responds to the instruction. The function is executed (waiting for an interrupt). That is, in the standby state, the CPU of the mobile phone 1 is in an interrupt waiting state.

  Further, when entering the standby state, the CPU of the mobile phone 1 starts a timer 0 interrupt counter and a timer 1 interrupt counter.

  The timer 0 interrupt counter is a timer for generating (executing) a predetermined interrupt event (operation executed by the mobile phone 1) every predetermined period, and a predetermined period is set for each interrupt event. . When this counter counts (counts) the predetermined period, the CPU of the mobile phone 1 executes an interrupt event corresponding to the predetermined period.

  Hereinafter, in this embodiment, the types of interrupt events are identified as timer 0 interrupts and timer 1 interrupts, and the counters set for the interrupt events are referred to as a timer 0 interrupt counter and a timer 1 interrupt counter.

  In this embodiment, the predetermined time corresponding to the timer 0 interrupt is set to 1 second (S), and the CPU of the mobile phone 1 transitions to the registered state after 1 second has elapsed from the standby state. It is supposed to be.

  In the present embodiment, the predetermined time corresponding to the timer 1 interrupt is set to 60 (S), and the CPU of the mobile phone 1 transitions to the search state after 60 seconds have elapsed from the standby state. It is like that.

  The predetermined time corresponding to the timer 0 interrupt and the timer 1 interrupt can be arbitrarily set in consideration of the usage state of the user. It is also possible not to set (that is, invalidate) the timer 0 interrupt and the timer 1 interrupt, respectively.

  In addition, priorities can be assigned to the interrupt events, and the CPU of the mobile phone 1 executes the interrupt events according to the priorities. In addition, when the operation button is pressed, the CPU of the mobile phone 1 according to the present embodiment executes an event corresponding to the pressed operation button in preference to the interrupt event.

  In the state chart shown in FIG. 3, the CPU of the mobile phone 1 executes the timer 0 interrupt with priority over the timer 1 interrupt.

  As described above, the timer 0 interrupt and the timer 1 interrupt always operate, and when the count-up reaches the set value, an interrupt request is output and the count-up is restarted from 0.

  For example, by setting timer 0 interrupt to 1 second and timer 1 interrupt to 60 seconds, smooth registration (waiting time 1 second) and reasonable security (security mode (lock) start 60 seconds after leaving) it can.

  Returning to the description of FIG. 3, the CPU of the mobile phone 1 transitions to the registration state when the timer 0 interrupt counter counts that one second has elapsed.

  This registration state refers to a state in which the CPU of the mobile phone 1 executes the process defined in the registration mode described above. Specifically, the CPU of the mobile phone 1 has a communication range 11 (second communication range of the present application) narrower than the communication range 10 (an example of the first communication range of the present application) via the communication control unit. The identification information request signal is transmitted in order to read the identification information stored in the RFID tag existing in (an example of the above) (that is, the second communication range carrier ON state).

  Specifically, as shown in FIG. 4, the CPU of the mobile phone 1 reduces the electric field strength of the signal so that the communication range 11 is narrower than the communication range 10 (for example, the communication range is several centimeters). The identification information stored in the RFID tag existing at 10 cm to 10 cm) is read.

  In the example illustrated in FIG. 4, the CPU of the mobile phone 1 reads the identification information of the RFID tag 2 </ b> A attached to the wallet 2 via the communication control unit. Then, the CPU of the mobile phone 1 stores the read identification information in the storage unit. In the registration mode, the CPU of the mobile phone 1 cannot read the identification information of the RFID tag 3A attached to the notebook 3 where the communication range 10 exists.

  Normally, when the user registers (reads) the identification information in the CPU of the mobile phone 1, the user brings the RFID tag storing the identification information that is a registration target (read target) close to the mobile phone 1. There are many cases.

  Accordingly, in the registration mode, the CPU of the mobile phone 1 surely reads the identification information of the RFID tag attached to the article (for example, the wallet 2 in FIG. 4) that is close to the mobile phone 1 as a registration target. Can do. The CPU of the mobile phone 1 is not supposed to be registered by the user, and does not read the identification information of the RFID tag attached to the article (for example, the notebook 3 in FIG. 4) isolated from the mobile phone 1. The data can be read and registered reliably from the data reading target.

  Returning to the description of FIG. 3, when the CPU of the mobile phone 1 reads the identification information stored in the RFID tag, a screen for selecting whether to store the read identification information in the storage unit is not illustrated. Show on the display. And if the said identification information is registered into the memory | storage part of the mobile telephone 1 by operation of the operation part by a user, CPU of the mobile telephone 1 will change to a standby state (waiting command of FIG. 3).

  In the registration state, when the CPU of the mobile phone 1 cannot read the identification information, the mobile phone 1 may be shifted to a standby state.

  When the timer 1 interrupt counter counts that 60 seconds have elapsed, the CPU of the mobile phone 1 transitions to the search state. This search time is preferably performed every predetermined time for power saving.

  This search state means a state where the security lock is executed by the CPU of the mobile phone 1 and an RFID tag existing around the mobile phone 1 is searched.

  Then, as described above, the CPU of the mobile phone 1 collates the registered identification information with the identification information read from the RFID tag attached to the article carried by the user of the mobile phone existing within the communication range. If they match, the security lock is released.

  Specifically, as shown in FIG. 4, when the CPU of the mobile phone 1 transitions to the search state, it is stored in the RFID tag that exists in the communication range 10 wider than the communication range 11 via the communication control unit. In order to read the identification information, the identification information request signal is transmitted by switching to a strong electric field strength.

  In the example shown in FIG. 4, the CPU of the mobile phone 1 sends the identification information of the RFID tag 2A attached to the wallet 2 within the communication range 10 and the RFID tag attached to the notebook 3 via the communication control unit. 3A identification information is read.

  At this time, it is assumed that the identification information of the RFID tag attached to the wallet carried by the user and the identification information of the RFID tag 3A attached to the notebook 3 are registered as the registered identification information. The CPU of the mobile phone 1 detects from the reading result of the identification information that all the registered identification information matches all the identification information read in the search state.

  Then, the CPU of the mobile phone 1 considers that the user exists around the mobile phone and releases the security lock.

  In the present embodiment, the CPU of the mobile phone 1 releases the security lock when all registered identification information matches all identification information read in the search state. However, the security lock may be released when a part (that is, a predetermined quantity) of all registered identification information matches the identification information read in the search state.

  Then, when releasing the security lock, the CPU of the mobile phone 1 stops transmitting the identification information transmission request signal and transitions to a standby state.

  Further, when the timer 0 interrupt counter counts that one second has elapsed, the CPU of the mobile phone 1 transitions to the registration state.

  Returning to the description of FIG. 3, when there is a user instruction in the registration state (when a user interface button (not shown) is pressed by a user operation), or when a user instruction is issued in the standby state (for example, a user not shown). When the interface button is pressed), the CPU of the mobile phone 1 transitions to the management state.

  This management state refers to a process for changing information of an RFID tag registered in the registration state. Specifically, in the registration state, the CPU of the mobile phone 1 deletes the identification information of the already registered RFID tag and registers the identification information of the RFID tag based on the user's operation.

  When there is an instruction from the user in the management state, or when a predetermined period has elapsed, the state transits to the standby state. When there is a user instruction in the management state, the state transits to the registration state or the search state.

B) Second Embodiment Next, details of the second embodiment of the registration mode will be described with reference to FIGS.

  FIG. 5 is a state chart showing the operation of the CPU of the mobile phone 1 in the second embodiment, and FIG. 6 shows the range in which the CPU of the mobile phone 1 in the second embodiment reads the identification information of the RFID tag. FIG. Note that the state chart diagram in FIG. 3 and the state chart diagram in FIG. 5 are the same except for the transmission method of the identification information transmission request transmitted by the CPU of the mobile phone 1. Therefore, description of common parts is omitted, and a method for transmitting an identification information transmission request will be described below.

  In the second embodiment, the CPU of the mobile phone 1 switches between the communication standard of the identification information request signal transmitted during execution of the security lock and the communication standard of the identification information request signal transmitted in the registration mode. This is a form when a request signal is transmitted.

  Specifically, as shown in FIG. 6, the wallet 2 has a communication standard (an example of the first communication standard of the present application, which enables data communication with the mobile phone 1 within the communication range 20. , "The communication standard within the communication range 20") and the communication standard (the second communication of the present application) that enables data communication between the RFID tag 2A and the mobile phone 1 within the communication range 21. An example of a standard, hereinafter referred to as “communication standard within communication range 21”) is attached.

  In the notebook 3, the RFID tag 3A corresponding to the communication standard that enables data communication with the mobile phone 1 within the communication range 20 and the data between the mobile phone 1 within the communication range 21 are stored. An RFID tag 3B corresponding to a communication standard that enables communication is attached.

  Identification information indicating the RFID tag is stored in the RFID tag 2A and the RFID tag 3A. The RFID tag 2B stores identification information indicating the RFID tag and identification information indicating the RFID tag 2A. Similarly, identification information indicating the RFID tag and identification information indicating the RFID tag 3A are stored in the RFID tag 3B.

  First, when the CPU of the mobile phone 1 transitions to the search state (that is, during execution of security lock, see FIG. 5), the RFID tag existing in the communication range 20 shown in FIG. To read the stored identification information, an identification information request signal is transmitted (search mode carrier wave ON).

  As described above, within the communication range 20, the CPU of the mobile phone 1 communicates with only the RFID tag 2 </ b> A and the RFID tag 3 </ b> A corresponding to the communication standard within the communication range 20 (e.g., ISO / IEC 18000-2 described above) Data communication between them is possible.

  Therefore, in this case, the CPU of the mobile phone 1 can read the identification information stored in the RFID tag 2A and the RFID tag 3A.

  Next, when the CPU of the mobile phone 1 transitions to the registration state (that is, the registration mode, see FIG. 5), the communication standard is arbitrarily switched, so that the communication range is more than 20 within the communication range. In order to read the identification information stored in the RFID tag existing within the narrow communication range 21, an identification information request signal is transmitted (security lock carrier wave ON).

  Specifically, the CPU of the mobile phone 1 transmits an identification information request signal corresponding to the communication standard within the communication range 21 (switching from the first communication standard to the second communication standard). Here, it is assumed that the RFID tag 2A attached to the wallet 2 is assumed as a reading target.

  Here, within the communication range 21, the CPU of the mobile phone 1 conforms to the communication standard within the communication range 21 (for example, the above-described ISO / IEC 18000-3 etc., which is a communication standard different from ISO / IEC 18000-2). Data communication is possible only with the corresponding RFID tag 2B and RFID tag 3B.

  Therefore, in this case, the CPU of the mobile phone 1 reads the identification information indicating the RFID tag and the identification information indicating the RFID tag 2A stored in the RFID tag 2B existing within the communication range 21 and stores them in the storage unit. It has become. That is, the identification information of the RFID tag 3A attached to the notebook 3 that is not the reading target is not read.

  As described above, in the registration mode, the CPU of the mobile phone 1 transmits the identification information request signal switched to the communication standard capable of communication in a narrower range than the communication standard of the identification information request signal transmitted during execution of the security lock. To do.

  Therefore, in the registration mode, the CPU of the mobile phone 1 can surely read the identification information of the RFID tag attached to the article that is close to the mobile phone 1 as a registration target. The CPU of the mobile phone 1 is not supposed to be registered by the user and does not read the identification information of the RFID tag affixed to the article isolated from the mobile phone 1, so that the data is reliably read from the data read target. Can be registered.

  Further, when the security lock is executed and the identification information stored in the RFID tag 2A existing within the communication range 20 is read, the CPU of the mobile phone 1 collates with the stored identification information indicating the RFID tag 2A. If they match, the security lock is released.

  The embodiments described above do not limit the invention according to the claims. And not all the combinations of the configurations described in the above embodiment are indispensable means for solving the problems of the invention.

  Also, a program corresponding to the state chart shown in FIG. 3 or FIG. 5 is recorded on a recording medium such as a flexible disk or a hard disk, or is acquired and stored via a network, and these are stored in a general-purpose micro computer. It is possible to cause the microcomputer or the like to function in the same manner as the operation indicated by the CPU of the mobile phone 1 according to the above-described embodiment by causing the computer or the like to read and execute the microcomputer.

  As described above, when reading the identification information, the CPU of the mobile phone 1 reads the identification information stored in the RFID tag from the RFID tag existing in the first communication range, and when registering the identification information, Since the identification information stored in the RFID tag is read from the RFID tag existing in the second communication range that is narrower than the first communication range, the data is reliably read from the data reading target. You can register.

  In the above embodiment, an example in which the present application is applied to the security lock system has been shown. However, for example, the present application is also applied to a forgotten object detection system or an entry / exit management system using an RFID chip. can do.

DESCRIPTION OF SYMBOLS 1 Cellular phone 2 Wallet 2A RFID tag 2B RFID tag 3 Notebook 3A RFID tag 3B RFID tag 4 Watch 4A RFID tag S Security lock system

Claims (5)

A terminal device that performs reading and registration of data stored in an RFID tag in a non-contact communication method within a communication range in which data communication is possible,
At the time of reading, a first communication means for reading identification information stored in the RFID tag from an RFID tag existing in the first communication range;
A second communication means for reading identification information stored in the RFID tag from an RFID tag existing in a second communication range narrower than the first communication range at the time of registration;
Registration means for registering identification information read by the second communication means;
Communication control means for switching between the first communication means and the second communication means;
A terminal device comprising: The terminal device according to claim 1,
The terminal device according to claim 2, wherein the second communication means controls the electric field strength in the second reading range to be weaker than the electric field strength in the first reading range. The terminal device according to claim 1,
The first communication means is stored in an RFID tag corresponding to the first communication standard in accordance with a first communication standard that defines a communication standard that enables data communication with a specific RFID tag. Read the identification information of the RFID tag,
The second communication means is stored in an RFID tag corresponding to the second communication standard according to a second communication standard that defines a communication standard that enables data communication with a specific RFID tag. A terminal device that reads identification information of an RFID tag corresponding to the first communication standard. A data reading method in a terminal device that performs reading and registration of data stored in an RFID tag in a non-contact communication method within a communication range in which data communication is possible,
A first communication step of reading the identification information stored in the RFID tag from the RFID tag present in the first communication range at the time of the reading;
A second communication step of reading the identification information stored in the RFID tag from the RFID tag present in the second communication range narrower than the first communication range at the time of the registration;
A registration step of registering the identification information read by the second communication means;
A communication control step of switching between the first communication means and the second communication means;
A data reading method characterized by comprising: A computer included in a terminal device that performs reading and registration of data stored in an RFID tag in a non-contact communication method within a communication range in which data communication is possible.
A first communication means for reading identification information stored in the RFID tag from the RFID tag existing in the first communication range at the time of reading;
A second communication unit that reads identification information stored in the RFID tag from an RFID tag that exists in a second communication range narrower than the first communication range at the time of registration;
Registration means for registering identification information read by the second communication means;
Communication control means for switching between the first communication means and the second communication means;
A data reading program characterized by functioning as

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