JP2011060169A - Portable communication terminal, host communication device, and rfid system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a portable communication terminal not requiring a dedicated charger, and prevented from being left in an uncharged state, and also to provide an RFID system provided with the portable communication terminal and a host communication device. <P>SOLUTION: This portable communication terminal 200 is equipped with: an antenna 201 for communication with the host communication device 300; an electric power converting circuit 202 for converting an induced electromotive force induced in the antenna 201 into a direct current voltage; and a storage battery 203. The propriety of charging the storage battery 203 is determined by comparing either of a reference value provided in the portable communication terminal 200 or a reference value set in the host communication device 300 by a user of the RFID system, with a residual amount in the storage battery 203. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to an RFID system, a portable communication terminal, and a host communication device including a portable communication terminal that communicates with an RFID tag (Radio Frequency IDentification) and a host communication device that communicates with the portable communication terminal. The present invention relates to power control of a mobile communication terminal.

  In recent years, RFID tags have been remarkably miniaturized and reduced in price, and moreover, since they can handle an overwhelmingly large amount of information compared to barcodes, they have been attached to many products and products. For example, information such as the contents of merchandise displayed in a store and distribution history is stored in the memory of an RFID tag attached to the merchandise, and the consumer simply brings the reader / writer close to the target merchandise. It became possible to confirm the information of.

  Further, since the RFID tag has a short-range communication function, various information can be collected by transmitting information detected by the sensor from the RFID tag to the reader / writer in combination with various sensors. The sensor combined with the RFID tag may be any sensor such as a temperature sensor, a pressure sensor, a light amount sensor, or a magnetic sensor.

  When an RFID tag is combined with a sensor and information detected by the sensor is received as data by a reader / writer, some sensors may not be able to move to the vicinity of the reader / writer. In such a case, the reader / writer must be moved close to the RFID tag to acquire information detected by the sensor from the target RFID tag. For this purpose, the reader / writer must be a portable communication terminal and battery driven. Since a storage battery is normally used as the power source for such a mobile communication terminal, a charging device is required. In addition, when the reader / writer is a portable communication terminal, the data processing capability is reduced because the reader / writer is as small as possible and consumes less power. In order to compensate for this, data acquired by a normal mobile communication terminal is transmitted to a host communication device, and the host communication device stores and manages the data. In such an RFID system, a charging method of a storage battery built in the mobile communication terminal becomes a problem.

  When the voltage of the storage battery built in the wireless card drops below a predetermined value, Patent Literature 1 displays that fact and informs the necessity of charging. When the wireless card is inserted into the radio charger, the radio card irradiates the radio card with charging radio waves, and charging is performed.

  Patent Document 2 communicates between a non-contact IC card using a battery and an interrogator by using the electromagnetic induction action of the coil, and uses the electric power generated by the electromagnetic induction action using the coil. Power is supplied to the main circuit portion of the IC card to operate the non-contact IC card and to charge the built-in battery.

  However, in Patent Document 1, a dedicated charging device is required, and if a display indicating that charging is necessary is missed, the wireless card is used without being charged, and the wireless card battery runs out during use. There is. There is also a problem that the wireless card cannot be used during charging. In Patent Document 2, since the IC card is charged when the IC card communicates with the interrogator, it is no longer necessary to forget to charge. Both Patent Document 1 and Patent Document 2 are provided with a storage battery as a power source for the IC card. However, since the power consumed by the IC card is usually very small, the capacity of the storage battery built in the IC card is sufficient. For this reason, as in Patent Document 2, the storage battery can be charged even in a short time during which the IC card is communicating with the interrogator, but the portable communication terminal that can also be used as a reader / writer described in the background art In this case, since the capacity of the built-in storage battery is large, the storage battery cannot be charged until it is fully charged only by the time when the mobile communication terminal communicates with the interrogator.

  An object of the present invention is to solve the above problems, and in an RFID system including a portable communication terminal that communicates with an RFID tag and a host communication device that communicates with the portable communication terminal, a dedicated charging device is unnecessary and charging is performed. An object of the present invention is to provide an unforgettable portable communication terminal and an RFID system including the portable communication terminal and a host device.

A mobile communication terminal according to the present invention is a mobile communication terminal for an RFID system including a mobile communication terminal and a host communication device.
An antenna used for communication with the RFID tag and the host communication device;
A storage battery,
The storage battery is charged until it is fully charged by an induced electromotive force induced in the antenna by radio waves output from the host communication device.

The portable communication terminal is
Reader / writer mode that functions as a reader / writer,
It has a tag mode that functions as an RFID tag,
When communicating with the RFID tag, it operates in a reader / writer mode,
In response to a start command from the host communication device, operates in tag mode,
When the host communication device is activated, it operates in a reader / writer mode and transmits an activation command to the host communication device.

Further, the mobile communication terminal is
When operating in the reader / writer mode and communicating with the RFID tag or the host communication device, the storage battery is used,
When operating in the tag mode and communicating with the host communication device, select and use either the storage battery or the induced electromotive force induced in the antenna according to a predetermined switching signal. It is characterized by.

Still further, the portable communication terminal is
A power conversion circuit that converts the induced electromotive force induced in the antenna into a DC voltage and outputs the DC voltage;
Power line switching means for selecting one of the induced electromotive force and the storage battery;
A transmission / reception control circuit for controlling transmission / reception of data using the antenna;
An auto / manual switch for switching the operation of the mobile communication terminal;
A controller for controlling the operation of the mobile communication terminal,
The auto / manual switch outputs an auto or manual signal to the controller,
The controller is
A remaining amount detection function for detecting the remaining amount of the storage battery;
Determining whether to charge the storage battery, and a charge control function for controlling the charging of the storage battery;
The power supply line switching unit includes a power supply line control function for outputting the switching signal.

In the mobile communication terminal, the switching signal is:
When the signal of the auto / manual switch is auto, the induced electromotive force is selected if the remaining amount of the storage battery is less than a predetermined reference value, and if the remaining amount of the storage battery is greater than or equal to the predetermined reference value Select the storage battery,
When the signal of the auto / manual switch is manual, the remaining amount of the storage battery is transmitted to the host communication device, and in response to a power designation command received from the host communication device, the induced electromotive force and the storage battery One of them is selected.

  Furthermore, the portable communication terminal starts a charging operation in response to a charging command transmitted from the host communication device.

Still further, the portable communication terminal checks the remaining amount of the storage battery using the remaining amount detection function in response to the charging command,
When the signal of the auto / manual switch is auto, charging is started if the remaining amount of the storage battery is less than a predetermined reference value,
When the signal of the auto / manual switch is manual, the remaining amount of the storage battery is transmitted to the host communication device, and charging is started in response to a charge availability command received from the host communication device.

  The portable communication terminal transmits and receives commands to and from the host communication device during charging of the storage battery.

  Furthermore, the portable communication terminal further includes display means for displaying that the storage battery is being charged.

  Furthermore, in the portable communication terminal, the full charge of the storage battery is detected by the remaining amount detection function.

In addition, the mobile communication terminal includes a communication switch that is manually operated to turn on its own power supply,
When the power is turned on by operating the communication switch, the mobile communication terminal operates in the reader / writer mode,
When the mobile communication terminal is powered off, the mobile communication terminal operates in the tag mode if the host communication device is activated and the power is turned on.

Furthermore, the mobile communication terminal includes storage means for storing ID information of the mobile communication terminal and data acquired from the RFID tag,
At the time of communication with the host communication device, the ID information and the data stored in the storage means are transmitted to the host communication device.

  Still further, in the portable communication terminal, the storage means is a nonvolatile memory.

A host communication device according to the present invention is a host communication device for an RFID system including a mobile communication terminal and a host communication device.
Reader / writer mode that functions as a reader / writer,
It has a tag mode that functions as an RFID tag,
When the mobile communication terminal is activated, it operates in a reader / writer mode,
It operates in a tag mode in response to an activation command from the portable communication terminal.

In addition, the host communication device
When operating in the reader / writer mode and receiving the remaining amount of the storage battery from the mobile communication terminal,
If the remaining amount is less than a first reference value that can be set by the user, the power supply designation command for designating the induced electromotive force is transmitted to the mobile communication terminal,
If the remaining amount is equal to or greater than the first reference value, the power designation command designating the storage battery is transmitted to the mobile communication terminal.

Furthermore, the host communication device includes:
When operating in the reader / writer mode, after transmitting the charging command to the mobile communication terminal, when the remaining amount of the storage battery is received from the mobile communication terminal,
If the remaining amount is less than a second reference value that can be set by the user, a charge enable / disable command designated to perform charging is transmitted to the mobile communication terminal,
If the remaining amount is equal to or greater than the second reference value, a charge enable / disable command that designates not to perform charging is transmitted to the mobile communication terminal.

Still further, the host communication device includes a mounting receiving unit to which the mobile communication terminal is mounted,
When the mobile communication terminal is mounted on the mounting receiver, the mobile communication terminal is turned on.

  An RFID system according to the present invention includes the portable communication terminal and the host communication device.

  According to the present invention, when the mobile communication terminal is operating in the reader / writer mode, power is supplied from the storage battery. When the mobile communication terminal is operating in the tag mode, the signal of the auto / manual switch and the remaining capacity of the storage battery are supplied. In response to this, it is determined whether to use a storage battery or to use a DC voltage converted from an induced electromotive force. When the signal of the auto / manual switch is auto, the reference value provided in the mobile communication terminal is compared with the remaining amount of the storage battery, and when the remaining amount is equal to or greater than the reference value, the storage battery is used. On the other hand, in the case of a manual, the reference value set by the user in the host communication device is compared with the remaining amount of the storage battery, and the storage battery is used when the remaining amount is greater than or equal to the reference value. Thereby, the user can set the remaining amount of the storage battery when the mobile communication terminal uses the DC voltage converted from the induced electromotive force, and the remaining amount of the storage battery can be managed by the host communication device.

  The storage battery built in the mobile communication terminal is charged by an instruction from the host communication device when the mobile communication terminal transmits data acquired from the RFID tag to the host communication device. As a result, a dedicated charger is not required, and charging is performed in association with communication with the host communication apparatus, which is a normal operation. Furthermore, since the storage battery is charged using a DC voltage converted from the induced electromotive force induced in the communication antenna of the mobile communication terminal, an antenna dedicated to charging is not required, and the mobile communication terminal can be downsized. Furthermore, since the remaining amount of the storage battery that starts charging the storage battery is determined based on the reference value set by the user in the host communication device, an appropriate charge start remaining amount can be set even if the type or capacity of the battery changes. Furthermore, when charging of the storage battery is started, charging is continued until the storage battery is fully charged. Therefore, when the mobile communication terminal is operated in the reader / writer mode, the storage battery can always be used in a fully charged state.

1 is a block diagram illustrating an RFID system according to an embodiment of the present invention. 4 is a flowchart showing communication processing with the RFID tag 100 by the mobile communication terminal 200 of FIG. 1. It is a flowchart which shows the determination process of the power supply used by the mobile communication terminal 200 of FIG. 6 is a flowchart showing a determination process of a power source used by the host communication apparatus 300 of FIG. 1. It is a flowchart which shows the 1st part of the charging process by the mobile communication terminal 200 (tag mode) of FIG. It is a flowchart which shows the 2nd part of the charging process by the mobile communication terminal 200 (tag mode) of FIG. It is a flowchart which shows the 3rd part of the charging process by the mobile communication terminal 200 (tag mode) of FIG. 6 is a flowchart showing a first part of a charging process by the host communication apparatus 300 (reader / writer mode) in FIG. 1. 6 is a flowchart showing a second part of a charging process by the host communication device 300 (reader / writer mode) in FIG. 1.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

  FIG. 1 is a block diagram showing an RFID system according to an embodiment of the present invention. The RFID system includes an RFID tag 100, a portable communication terminal 200, and a host communication device 300.

  First, the RFID tag 100 will be described. The RFID tag 100 is attached to, for example, a temperature sensor, and transmits data measured by the sensor and its own ID information to the mobile communication terminal 200. The RFID tag 100 operates at a voltage obtained by rectifying radio waves transmitted from the mobile communication terminal 200.

  Next, the mobile communication terminal 200 will be described. The mobile communication terminal 200 includes, as operation modes, a reader / writer mode that operates as a reader / writer, and a tag mode that operates as an RFID tag. When communicating with the RFID tag 100, the mobile communication terminal 200 operates in the reader / writer mode, and acquires ID information and data from the RFID tag 100. Further, when communicating with the host communication device 300, it operates in either the tag mode or the reader / writer mode depending on the activation method of the mobile communication terminal 200. When the mobile communication terminal 200 is activated by pressing a communication switch 207 provided in the mobile communication terminal 200, the mobile communication terminal 200 operates in the reader / writer mode. At this time, the mobile communication terminal 200 transmits an activation command to the host communication device 300 to activate the host communication device 300, and then transmits a command, ID information, and data to the host communication device 300. On the other hand, when the mobile communication terminal 200 is activated by receiving an activation command from the host communication device 300, the mobile communication terminal 200 operates in the tag mode, and the ID information and data are received according to the command of the host communication device 300. Send to.

  The portable communication terminal 200 includes an antenna 201, a power conversion circuit 202, a storage battery 203, a power line switching unit 204, a charge switching unit 205, a transmission / reception control circuit 206, a communication switch 207, and an auto / manual switch 208. , A memory 209, a display unit 210, and a controller 211.

  The antenna 201 transmits and receives radio waves between the RFID tag 100 and the host communication device 300. The induced electromotive force induced in the antenna 201 is used for operating the internal circuit 212 and charging the storage battery 203. The power conversion circuit 202 rectifies the induced electromotive force induced in the antenna 201 and outputs it as a DC voltage via a constant voltage circuit or the like. As will be described later, this DC voltage is used as a power supply voltage when the mobile communication terminal 200 operates in the tag mode and as a power supply voltage for charging the storage battery 203.

  The storage battery 203 is used as a power source when the mobile communication terminal 200 operates in the reader / writer mode, and may be used as a power source when the mobile communication terminal 200 operates in the tag mode. When the storage battery 203 is charged, a DC voltage converted from the induced electromotive force by the power conversion circuit 202 is used. As the storage battery 203, a secondary battery such as a lithium ion battery or a nickel metal hydride battery, or a large capacity capacitor such as an electric double layer capacitor is used.

  The power line switching unit 204 is controlled by a switching signal S 1 from the controller 211, selects one of the DC voltage from the power conversion circuit 202 and the DC voltage from the storage battery 203 and passes through the power supply line 213. To the internal circuit 212. The charge switching unit 205 is controlled by a switching signal S2 from the controller 211, and switches whether to charge by switching whether to output the DC voltage from the power conversion circuit 202 to the storage battery 203.

  The transmission / reception control circuit 206 receives commands, ID information, and data from the controller 211 and transmits them to the RFID tag 100 and the host communication device 300 via the antenna 201. The transmission / reception control circuit 206 receives commands, ID information, and data from the RFID tag 100 and the host communication device 300 via the antenna 201 and outputs them to the controller.

  The communication switch 207 is a manual push button type power switch of the mobile communication terminal 200. The communication switch 207 is connected to the controller 211. When the communication switch 207 is pressed, the power of the mobile communication terminal 200 is turned on, the mobile communication terminal 200 operates in the reader / writer mode, and the RFID tag 100 or host communication Communicates with device 300. When the communication is completed, the mobile communication terminal 200 is automatically turned off after a certain time. When the communication switch 207 is pressed again after the communication is completed and before the power is automatically turned off, the communication is resumed.

  The auto / manual switch 208 is a switch for switching the operation of the mobile communication terminal 200 and is connected to the controller 211. By switching the auto / manual switch 208, an auto or manual signal is output to the controller 211. Depending on whether auto or manual is selected, the operation for determining the power source used by the mobile communication terminal 200 and the operation for charging the storage battery 203 change. Details of the operation will be described in the following operation of the present embodiment.

  The memory 209 is connected to the controller 211 and stores and stores commands used for communication with the RFID tag 100 or the host communication device, ID information of the mobile communication terminal 200, and data acquired from the RFID tag 100. Command, ID information, and data are output to the controller 211. The memory 209 is configured by a non-volatile memory in case the voltage of the storage battery 203 decreases.

  The display unit 210 is connected to the controller 211 and displays information necessary for the user of the RFID system. For example, the power on / off state of the mobile communication terminal 200, the remaining amount of the storage battery 203, whether the storage battery 203 is being charged, whether it is communicating with an RFID tag or a host communication device, and the presence / absence of a communicable RFID tag. indicate. The display unit includes an LED and a liquid crystal display.

  The controller 211 controls each circuit of the mobile communication terminal 200 and includes a remaining amount detection function, a charge control function, and a power line control function. In the remaining amount detection function, the controller 211 detects the remaining amount of the storage battery 203 by measuring the voltage and current of the storage battery 203. In the charge control function, the controller 211 receives the operation mode of the mobile communication terminal 200, the remaining amount of the storage battery 203 output from the remaining amount detection function, and the host communication device 300 via the antenna 201 and the transmission / reception control circuit 206. Based on the received command and the auto or manual signal output from the auto / manual switch 208, the switching signal S2 is output to control the charge switching unit 205. Further, in the power supply line control function, the controller 211 includes the host communication device 300 via the operation mode of the mobile communication terminal 200, the remaining amount of the storage battery 203 output from the remaining amount detection function, the antenna 201 and the transmission / reception control circuit 206. Based on the command received from the auto / manual switch 208 and the auto / manual signal output from the auto / manual switch 208, the switching signal S1 is output to control the power line switching unit 204. The controller 211 is configured by hardware, software, or a combination thereof.

  Next, the host communication device 300 will be described. The host communication device 300 communicates with the mobile communication terminal 200, acquires ID information and data stored in the memory 209 of the mobile communication terminal 200, and stores and manages them. The host communication device 300 includes, as operation modes, a reader / writer mode that operates as a reader / writer and a tag mode that operates as an RFID tag. Which mode is used depends on the startup method of the host communication device 300. When the mobile communication terminal 200 is attached to an attachment receiver (not shown) provided in the host communication device 300, the host communication device 300 operates in the reader / writer mode. At this time, the host communication device 300 transmits an activation command to the mobile communication terminal 200 to perform communication by operating the mobile communication terminal 200 in the tag mode regardless of the operation of the communication switch 207, and When the amount is small, power for charging is supplied via the antenna 201. On the other hand, when the host communication device 300 is activated by receiving the activation command from the mobile communication terminal 200, the host communication device 300 operates in the tag mode, and the ID information and data transmitted from the mobile communication terminal 200 are received. Receive, store and manage.

  As described above, according to the present embodiment, both the mobile communication terminal 200 and the host communication device 300 have a reader / writer mode that functions as a reader / writer and a tag mode that functions as an RFID tag as operation modes. .

Communication processing between the mobile communication terminal 200 and the RFID tag 100.
FIG. 2 is a flowchart showing communication processing with the RFID tag 100 by the mobile communication terminal 200 of FIG. Sn (n is an integer) attached to the left of each step is a step number for use in the following description.

  First, in step S21, it is checked whether or not the communication switch 207 of the mobile communication terminal 200 has been pressed. If not, step 21 is repeated until it is pressed. When the communication switch 207 is pressed in step S21, the mobile communication terminal 200 is turned on, and the mobile communication terminal 200 operates in the reader / writer mode. Note that the power supply voltage of the mobile communication terminal 200 at this time is supplied from the storage battery 203. Thereafter, in step S <b> 22, the mobile communication terminal 200 transmits and receives commands and data to and from the RFID tag 100. When the communication between the portable communication terminal 200 and the RFID tag 100 ends, the process moves to step S23, starts measuring the standby state time, and enters a standby state. At this time, the power source of the mobile communication terminal 200 is on, and a radio wave is output from the antenna 201 so that data from the RFID tag 100 can be received. In the standby state, it is determined whether or not the communication switch has been pressed (S24) and whether or not a predetermined standby time has elapsed (S25). When the communication switch 207 is pressed, the mobile communication terminal 200 returns to step S22 and resumes communication. When the communication switch 207 is not pressed, the standby state is continued. When the predetermined standby time has elapsed, the mobile communication terminal 200 is turned off and communication with the RFID tag 100 is terminated. On the other hand, if the predetermined standby time has not elapsed, the standby state is continued.

  As described above, according to the present embodiment, when the mobile communication terminal 200 communicates with the RFID tag 100, the mobile communication terminal 200 operates in the reader / writer mode and uses the storage battery 203 as a power source. The operation when the host communication apparatus 300 operates in the tag mode for communication is the same as that in FIG. Since the ID information received by the mobile communication terminal 200 during communication differs between the RFID tag 100 and the host communication device 300, the mobile communication terminal 200 determines whether the communication partner is the RFID tag 100 or the host communication device 300. Judgment can be made.

A process for determining the power source used by the mobile communication terminal 200.
FIG. 3 is a flowchart showing the determination process of the power source used by the mobile communication terminal 200 of FIG. 1, and FIG. 4 is a flowchart showing the determination process of the power source used by the host communication apparatus 300 of FIG.

  First, the operation of the mobile communication terminal 200 will be described with reference to FIGS. 1 and 3. It is assumed that the mobile communication terminal 200 is activated in either the reader / writer mode or the tag mode. In step S31, the operation mode of the mobile communication terminal 200 is confirmed. When operating in the reader / writer mode, the process moves to step S34, and it is determined that the storage battery 203 is to be used. At this time, the controller 211 controls the power supply line switching unit 204 with the switching signal S1. The power line switching unit 204 connects the storage battery 203 to the power supply line 213 and supplies a voltage from the storage battery 203 to the internal circuit 212. On the other hand, when operating in the tag mode, since the mobile communication terminal 200 is attached to the host communication device 300, the distance between the mobile communication terminal 200 and the host communication device 300 is short, and the power conversion circuit 202 includes the antenna 201. A sufficient DC voltage for operating the circuit of the portable communication terminal 200 can be generated from the induced electromotive force. In this case, the process proceeds to step S32, and the signal of the auto / manual switch input to the controller 211 is confirmed.

  When the signal of the auto / manual switch is auto, the process moves to step S33, and the controller 211 detects the remaining amount of the storage battery 203 using the remaining amount detection function and compares it with a predetermined reference value provided in the mobile communication terminal 200. . If the remaining amount is equal to or greater than the predetermined reference value, the process moves to step S34 and it is determined that the storage battery 203 is used. Subsequent operations are the same as those described above. On the other hand, if the remaining amount is less than the predetermined reference value, the process moves to step S35, and it is determined to use the DC voltage converted from the induced electromotive force. At this time, the controller 211 controls the power supply line switching unit 204 with the switching signal S1. The power supply line switching unit 204 connects the power conversion circuit 202 to the power supply line 213 and supplies a voltage to the internal circuit 212.

  Returning to step S32, the case where the signal of the auto / manual switch is manual will be described. In this case, the process moves to step S <b> 36, and the controller 211 detects the remaining amount of the storage battery 203 using the remaining amount detection function, and transmits the remaining amount to the host communication device 300 using the transmission / reception control circuit 206. Thereafter, in step S37, a power supply designation command transmitted from the host communication device 300 is waited for. In the power supply designation command transmitted by the host communication device 300, the power supply to be used by the mobile communication terminal 200 is designated. When the mobile communication terminal 200 receives the power designation command, the mobile communication terminal 200 moves to step S38 and determines the power designated by the power designation command. When the storage battery 203 is designated, it moves to step S34 and determines using the storage battery 203. Subsequent operations are the same as those described above. On the other hand, when the induced electromotive force is designated, it moves to step S35 and determines to use the DC voltage converted from the induced electromotive force. Subsequent operations are the same as those described above.

  Next, the operation of the host communication device 300 will be described with reference to FIGS. 1 and 4. The host communication device 300 operates in the reader / writer mode. In step S41, the host communication device 300 stands by for the remaining amount of the storage battery 203 transmitted from the mobile communication terminal 200. When the remaining amount of the storage battery 203 transmitted by the mobile communication terminal 200 in step S36 in FIG. 3 is received, the process moves to step S42, and the remaining amount is evaluated. In step S42, it is determined whether the mobile communication terminal 200 uses the storage battery 203 or the DC voltage converted from the induced electromotive force by comparing the transmitted remaining amount with the reference value in the host communication device 300. judge. If the remaining amount of the storage battery 203 is greater than or equal to the reference value, the process moves to step S43, determines that the storage battery 203 is to be used, and transmits a power supply designation command specifying the storage battery 203 to the mobile communication terminal 200. On the other hand, if the remaining amount of the storage battery 203 is less than the reference value, the process moves to step S44, where it is determined that the DC voltage converted from the induced electromotive force is used, and the power supply designation command designating the induced electromotive force is sent to the portable communication terminal 200.

  Note that the reference value used in step S42 can be set by the user using the RFID system, thereby setting the remaining amount of the storage battery 203 when the mobile communication terminal 200 is operated in the reader / writer mode. Can do. That is, when the reference value is set to a value close to full charge, the storage battery 203 is hardly used when the mobile communication terminal 200 is operated in the tag mode, so that the remaining amount of the storage battery 203 can be increased. As a result, when the mobile communication terminal 200 is operated in the reader / writer mode, the storage battery 203 has a capacity close to full charge, and the mobile communication terminal 200 can be used for a long time. Note that the reference value used in step S42 may be the same as or different from the reference value used in step S614 of FIG. 9 described later.

  As described above, according to the present embodiment, when the mobile communication terminal 200 operates in the reader / writer mode, power is supplied from the storage battery 203, and when the mobile communication terminal 200 operates in the tag mode, auto / Whether to use the storage battery 203 or a DC voltage converted from the induced electromotive force is determined according to the signal of the manual switch 208 and the remaining amount of the storage battery 203. When the signal of the auto / manual switch 208 is auto, the controller 207 compares the reference value provided in the mobile communication terminal 200 with the remaining amount of the storage battery 203. If the remaining amount is greater than the reference value, the controller 207 It is determined that the switch is to be used, and the switching signal S1 is output to the power supply line switching unit 204. On the other hand, when the signal of the auto / manual switch 208 is manual, the controller 207 transmits the remaining amount of the storage battery 203 to the host communication device 300, and the host communication device 300 allows the user to determine the received remaining amount. When the remaining amount is equal to or higher than the reference value, it is determined that the storage battery 203 is to be used, and a power supply designation command is transmitted to the mobile communication terminal 200. The mobile communication terminal 200 responds to the power supply designation command. The switching signal S1 is output to the power line switching unit 204. Thereby, the user can set the remaining amount of the storage battery 203 when the mobile communication terminal 200 uses the DC voltage converted from the induced electromotive force, and the remaining amount of the storage battery 203 can be managed by the host communication device 300.

Charging process for the storage battery 203 of the mobile communication terminal 200.
5 to 7 are flowcharts showing the charging process by the mobile communication terminal 200 (tag mode) in FIG. 1, and FIGS. 8 and 9 show the charging process by the host communication apparatus 300 (reader / writer mode) in FIG. It is a flowchart.

  First, the operation of the mobile communication terminal 200 will be described with reference to FIG. 1 and FIGS. In step S <b> 501, the mobile communication terminal 200 is attached to the attachment receiver of the host communication device 300. In step S <b> 502, the mobile communication terminal 200 stands by for an activation command transmitted from the host communication device 300. When the mobile communication terminal 200 receives the activation command, the power is turned on and the mobile communication terminal 200 is activated in the tag mode (step S503). Thereafter, the mobile communication terminal 200 waits for a command transmitted from the host communication device 300. There are at least three types of commands transmitted from the host communication device 300: an ID acquisition command, a data acquisition command, and a charging command. Whether or not these three types of commands have been received is determined in steps S504, S506, and S508, respectively. When the mobile communication terminal 200 receives the ID acquisition command, the mobile communication terminal 200 moves to step S505, reads out its own ID information from the memory 209, and transmits it to the host communication device 300. When the data acquisition command is received, the process proceeds to step S507, where necessary data is read from the memory 209 and transmitted to the host communication apparatus 300. In addition, when a charging command is received, a charging operation is started.

  In the charging operation, first, in step S509, the controller 211 detects the remaining amount of the storage battery 203 using the remaining amount detection function. In step S510, the auto / manual switch signal is checked. If it is auto, the process moves to step S511, the remaining amount checked in step S509 is compared with a predetermined reference value provided in the mobile communication terminal 200, and if it is equal to or greater than the reference value, the process returns to step S504 without charging. It waits for a command transmitted from the host communication device 300. On the other hand, if the remaining amount is less than the predetermined reference value, the process moves to step S515, where the controller 211 controls the charge switching unit 205 by the switching signal S2 and starts charging. As described above, the storage battery 203 is charged with a DC voltage converted from the induced electromotive force. When charging is started, the display unit 210 displays that charging is in progress in step S516. During charging, it is determined whether or not charging of the storage battery 203 has been completed (S517), and a command transmitted from the host communication device 300 in order to communicate with the host communication device 300 is determined (steps S518 and S520). And step S522). When the ID acquisition command or the data acquisition command is received, the same operation as described above is performed. However, when a charging command is received, nothing is done because charging is already in progress. The determination of completion of charging in step S517 is performed by the controller 211 using the remaining amount detection function. When the charging is completed, the process moves to step S523, where the controller 211 controls the charging switching unit 205 by the switching signal S2, and stops the charging. In step S524, the charging display is turned off, and the process returns to step S504 to wait for a command transmitted from the host communication device 300.

  Returning to step S510, the case where the signal of the auto / manual switch is manual will be described. In this case, the process moves to step S512, and the remaining amount of the storage battery 203 checked in step S509 is transmitted to the host communication device 300. Thereafter, the portable communication terminal 200 waits for a charge permission / inhibition command in step S513. The charge permission / prohibition command transmitted by the host communication device 300 specifies whether the mobile communication terminal should perform charging (charging is possible) or should not perform charging (charging is not permitted). When the mobile communication terminal 200 receives the charge enable / disable command, the mobile communication terminal 200 moves to step S514 and determines whether or not charge is possible. If the determination result is charging failure, the process returns to step S504 without charging and waits for the next command transmitted from the host communication device 300. On the other hand, if charging is possible, the process moves to step S515 to start charging. Since the operation after step S515 has already been described, a description thereof will be omitted.

  Next, the operation of the host communication device 300 will be described with reference to FIGS. In step S <b> 601, the mobile communication terminal 200 waits for attachment to the attachment receiving portion of the host communication apparatus 300. When detecting that the mobile communication terminal 200 is attached, the host communication apparatus 300 moves to step S602 and transmits an activation command to the mobile communication terminal 200. At this time, the operation mode of the host communication device 300 is the reader / writer mode.

  The host communication device 300 transmits a command to the mobile communication terminal 200 after starting the mobile communication terminal 200 in step S <b> 602. The command transmitted at this time includes (1) an ID acquisition command for acquiring ID information of the mobile communication terminal 200, and (2) data for acquiring data stored in the memory 209 of the mobile communication terminal 200. There are at least three of an acquisition command and (3) a charge command for charging the storage battery 203. A command to be transmitted to the mobile communication terminal 200 is determined in step S603, step S607, and step S611.

  When the host communication device 300 transmits an ID acquisition command, the host communication apparatus 300 moves to step S604, transmits the ID acquisition command, and then waits for ID information transmitted from the mobile communication terminal 200 in step S605. When the ID information is received, predetermined processing is executed based on the ID information sent from the mobile communication terminal 200 in step S606, and the process returns to step S603 to transmit the next command. When transmitting a data acquisition command, the process moves to step S608 to transmit the data acquisition command, and then waits for data transmitted from the mobile communication terminal 200 in step S609. When the data is received, a predetermined process is performed on the data transmitted from the mobile communication terminal 200 in step S610, and the process returns to step S603.

  When the host communication device 300 transmits a charge command, the host communication device 300 moves to step S612 and transmits a charge command, and then checks whether or not the remaining amount of the storage battery 203 has been received from the mobile communication terminal 200 in step S613. If the remaining amount has not been received, the process returns to step S603 to perform the next communication. When the remaining amount is received, the process moves to step S614, and the reference value in the host communication device 300 is compared with the received remaining amount. If the remaining amount is greater than or equal to the reference value, the process moves to step S615, determines that charging is not performed, and transmits a charge permission / inhibition command (charging not permitted) to the mobile communication terminal 200. On the other hand, when the remaining amount is less than the reference value, it is determined to charge, and a charge permission / inhibition command (charge possible) is transmitted to the mobile communication terminal 200. After transmitting the charge permission / inhibition command, the process returns to step S603 to prepare for the next command transmission. Note that the host communication device 300 continues to transmit radio waves for charging until charging of the mobile communication terminal 200 is completed.

  In step S614, the reference value used by the host communication device 300 can be set by the user of the RFID system. As a result, the user can determine the remaining amount of the storage battery 203 that starts charging the storage battery 203. Further, the reference value used in step S614 may be the same as or different from the reference value used in step S42 in FIG.

  As described above, according to the present embodiment, charging of the storage battery 203 built in the mobile communication terminal 200 is performed when the mobile communication terminal 200 transmits data acquired from the RFID tag 100 to the host communication device 300. This is performed in response to a charging command from the host communication device 300. As a result, a dedicated charger is not required, and charging is performed in association with communication with the host communication device 300, which is a normal operation. Further, since charging of the storage battery 203 uses a DC voltage converted from an induced electromotive force induced in the communication antenna 201 of the mobile communication terminal 200, an antenna dedicated to charging is not required, and the mobile communication terminal 200 can be downsized.

  Further, when the signal of the auto / manual switch 208 is auto, the controller 207 compares the reference value provided in the mobile communication terminal 200 with the remaining amount of the storage battery 203. If the remaining amount is less than the reference value, the storage battery 203 is charged. On the other hand, when the signal of the auto / manual switch 208 is manual, the controller 207 transmits the remaining amount of the storage battery 203 to the host communication device 300, and the host communication device 300 allows the user to determine the received remaining amount. If the remaining amount is less than the reference value, it is determined that the storage battery 203 is charged, and a charge enable / disable command is transmitted to the mobile communication terminal 200. The mobile communication terminal 200 responds to the charge enable / disable command. To charge the storage battery 203. As a result, since the remaining amount of the storage battery 203 that starts charging the storage battery 203 is determined based on the reference value set by the user in the host communication device 300, the appropriate remaining charge start remaining amount even if the battery type or capacity changes. Can be set.

  Furthermore, when charging of the storage battery 203 is started, charging is continued until the storage battery is fully charged. Therefore, when the mobile communication terminal 200 is operated in the reader / writer mode, the storage battery 203 should always be used in a fully charged state. Can do.

  As described above in detail, according to the portable communication terminal, the host communication device, and the RFID system according to the present invention, when the portable communication terminal is operating in the reader / writer mode, power is supplied from the storage battery, and the tag When operating in the mode, whether to use the storage battery or the DC voltage converted from the induced electromotive force is determined according to the signal of the auto / manual switch and the remaining amount of the storage battery. When the signal of the auto / manual switch is auto, the reference value provided in the mobile communication terminal is compared with the remaining amount of the storage battery, and when the remaining amount is equal to or greater than the reference value, the storage battery is used. On the other hand, in the case of a manual, the reference value set by the user in the host communication device is compared with the remaining amount of the storage battery, and the storage battery is used when the remaining amount is greater than or equal to the reference value. Thereby, the user can set the remaining amount of the storage battery when the mobile communication terminal uses the DC voltage converted from the induced electromotive force, and the remaining amount of the storage battery can be managed by the host communication device.

  The storage battery built in the mobile communication terminal is charged by an instruction from the host communication device when the mobile communication terminal transmits data acquired from the RFID tag to the host communication device. As a result, a dedicated charger is not required, and charging is performed in association with communication with the host communication apparatus, which is a normal operation. Furthermore, since the storage battery is charged using a DC voltage converted from the induced electromotive force induced in the communication antenna of the mobile communication terminal, an antenna dedicated to charging is not required, and the mobile communication terminal can be downsized. Furthermore, since the remaining amount of the storage battery that starts charging the storage battery is determined based on the reference value set by the user in the host communication device, an appropriate charge start remaining amount can be set even if the type or capacity of the battery changes. Furthermore, when charging of the storage battery is started, charging is continued until the storage battery is fully charged. Therefore, when the mobile communication terminal is operated in the reader / writer mode, the storage battery can always be used in a fully charged state.

100: RFID tag,
200 ... mobile communication terminal,
201 ... antenna,
202 ... power conversion circuit,
203 ... storage battery,
204 ... power line switching unit,
205 ... Charge switching unit,
206 ... transmission / reception control circuit,
207 ... communication switch,
208 ... Auto / manual switch,
209 ... Memory,
210 ... display section,
211 ... Controller,
212 ... internal circuit,
213 ... Power supply line,
300: Host communication device.

JP-A-7-154288. JP-A-11-345292.

Claims (18)

In a mobile communication terminal for an RFID system comprising a mobile communication terminal and a host communication device,
An antenna used for communication with the RFID tag and the host communication device;
A storage battery,
The mobile battery terminal according to claim 1, wherein the storage battery is charged by a radio wave output from the host communication device until the battery is fully charged by an induced electromotive force induced in the antenna. The mobile communication terminal is
Reader / writer mode that functions as a reader / writer,
It has a tag mode that functions as an RFID tag,
When communicating with the RFID tag, it operates in a reader / writer mode,
In response to a start command from the host communication device, operates in tag mode,
2. The portable communication terminal according to claim 1, wherein when the host communication device is activated, the portable communication terminal operates in a reader / writer mode and transmits an activation command to the host communication device. The mobile communication terminal is
When operating in the reader / writer mode and communicating with the RFID tag or the host communication device, the storage battery is used,
When operating in the tag mode and communicating with the host communication device, select and use either the storage battery or the induced electromotive force induced in the antenna according to a predetermined switching signal. The mobile communication terminal according to claim 1 or 2, wherein The mobile communication terminal is
A power conversion circuit that converts the induced electromotive force induced in the antenna into a DC voltage and outputs the DC voltage;
Power line switching means for selecting one of the induced electromotive force and the storage battery;
A transmission / reception control circuit for controlling transmission / reception of data using the antenna;
An auto / manual switch for switching the operation of the mobile communication terminal;
A controller for controlling the operation of the mobile communication terminal,
The auto / manual switch outputs an auto or manual signal to the controller,
The controller is
A remaining amount detection function for detecting the remaining amount of the storage battery;
Determining whether to charge the storage battery, and a charge control function for controlling the charging of the storage battery;
The mobile communication terminal according to claim 1, further comprising a power line control function for outputting the switching signal to the power line switching unit. The switching signal is
When the signal of the auto / manual switch is auto, the induced electromotive force is selected if the remaining amount of the storage battery is less than a predetermined reference value, and if the remaining amount of the storage battery is greater than or equal to the predetermined reference value Select the storage battery,
When the signal of the auto / manual switch is manual, the remaining amount of the storage battery is transmitted to the host communication device, and in response to a power designation command received from the host communication device, the induced electromotive force and the storage battery The mobile communication terminal according to claim 4, wherein any one of them is selected.   The mobile communication terminal according to claim 1, wherein the mobile communication terminal starts a charging operation in response to a charge command transmitted from the host communication device. The mobile communication terminal checks the remaining amount of the storage battery using the remaining amount detection function in response to the charging command,
When the signal of the auto / manual switch is auto, charging is started if the remaining amount of the storage battery is less than a predetermined reference value,
When the signal of the auto / manual switch is manual, the remaining amount of the storage battery is transmitted to the host communication device, and charging is started in response to a charge permission command received from the host communication device. Item 7. A mobile communication terminal according to Item 6.   The mobile communication terminal according to claim 6 or 7, wherein the mobile communication terminal transmits and receives commands to and from the host communication device during charging of the storage battery.   The mobile communication terminal according to claim 1, further comprising display means for displaying that the storage battery is being charged.   10. The mobile communication terminal according to claim 1, wherein full charge of the storage battery is detected by the remaining amount detection function. The mobile communication terminal includes a communication switch that is manually operated to turn on its own power supply,
When the power is turned on by operating the communication switch, the mobile communication terminal operates in the reader / writer mode,
3. The mobile communication according to claim 2, wherein the mobile communication terminal operates in the tag mode when the mobile communication terminal is powered off when the mobile communication terminal is powered off and activated. Terminal. The mobile communication terminal includes storage means for storing ID information of the mobile communication terminal and data acquired from the RFID tag,
The ID information and the data stored in the storage means are transmitted to the host communication device during communication with the host communication device. The portable communication terminal as described.   The portable communication terminal according to claim 12, wherein the storage means is a nonvolatile memory. In a host communication device for an RFID system comprising a mobile communication terminal and a host communication device,
Reader / writer mode that functions as a reader / writer,
It has a tag mode that functions as an RFID tag,
When the mobile communication terminal is activated, it operates in a reader / writer mode,
A host communication apparatus that operates in a tag mode in response to an activation command from the portable communication terminal. The host communication device is
When operating in the reader / writer mode and receiving the remaining amount of the storage battery from the mobile communication terminal,
If the remaining amount is less than a first reference value that can be set by the user, the power supply designation command for designating the induced electromotive force is transmitted to the mobile communication terminal,
The host communication device according to claim 14, wherein if the remaining amount is equal to or greater than the first reference value, the power supply designation command for designating the storage battery is transmitted to the mobile communication terminal. The host communication device is
When operating in the reader / writer mode, after transmitting the charging command to the mobile communication terminal, when the remaining amount of the storage battery is received from the mobile communication terminal,
If the remaining amount is less than a second reference value that can be set by the user, a charge enable / disable command designated to perform charging is transmitted to the mobile communication terminal,
The host communication device according to claim 14, wherein if the remaining amount is equal to or greater than the second reference value, a charge permission / prohibition command designating that charging is not performed is transmitted to the mobile communication terminal. The host communication device includes a mounting receiving unit to which the mobile communication terminal is mounted,
The host communication device according to claim 14, wherein when the portable communication terminal is attached to the attachment receiving unit, the portable communication terminal is turned on.   An RFID system comprising: the mobile communication terminal according to any one of claims 1 to 13; and the host communication device according to any one of claims 14 to 17.

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