JP2014235546A - Non-contact communication medium with sensory information transmission function, and power supply circuit control method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To make it possible to appropriately sense sensory information by reliably acquiring sufficient power to be able to drive a dot-matrix display type electronic paper module 29 from an external reading/writing device.SOLUTION: A power supply control circuit body 34 monitors an electric energy accumulated in an electric double-layer capacitor 33. If the electric energy reaches an energy necessary for transmission operation of a dot-matrix display type electronic paper module 29, a switch circuit 35 electrically connects the electric double-layer capacitor 33 and a step-up type switching control mode regulator power supply circuit 36. Alternatively, the power supply control circuit body 34 monitors an electric energy accumulated in the electric double-layer capacitor 33. If the electric energy reaches an energy necessary for transmission operation of the dot-matrix display type electronic paper module 29, it starts the step-up type switching control mode regulator power supply circuit 36 connected with the electric double-layer capacitor.

Description

  The present invention relates to a contactless communication medium with a sensory information transmission function and a power supply circuit control method.

  Conventionally, as a non-contact communication medium, for example, there is a technique described in Patent Document 1 (hereinafter referred to as a conventional non-contact communication medium). In this conventional non-contact communication medium, information is acquired from an AC magnetic field output from an external reader / writer, and sensory information is displayed on a display body based on the acquired information. Thereby, in the conventional non-contact communication medium, the display content (sensory information) of the display body is rewritten. At this time, in this conventional non-contact communication medium, power is acquired from an AC magnetic field output from an external reader / writer, and the display body is driven using the acquired power.

Japanese Patent Laid-Open No. 10-154215

However, in the above conventional non-contact communication medium, when the display body is driven using only the power obtained from the AC magnetic field without having a power source inside, the power obtained from the AC magnetic field is small, and the display body is driven appropriately. The display contents (sensory information) of the display body could not be properly rewritten unless the power as much as possible was obtained. For this reason, the conventional non-contact communication medium may not be able to properly transmit sensory information.
An object of the present invention is to make it possible to appropriately transmit sensory information by reliably acquiring sufficient power that can drive a sensory information transmitter from an external reader / writer, focusing on the above points.

In order to solve the above problems, in one embodiment of the present invention,
An IC chip having a wireless communication function for non-contact data communication with an external reader / writer, a first coil or antenna connected thereto, and an apparatus for transmitting sensory information based on information obtained through the IC chip (Hereinafter referred to as a sensory information transmitter), the second coil or antenna for operating power of the sensory information transmitter provided separately from the first coil or antenna, and the operation of the sensory information transmitter A non-contact communication medium with a sensory information transmission function having a power storage element, and a power supply circuit and a power supply control circuit connected to the power storage element, wherein the power supply control circuit monitors the power stored in the power storage element When the power necessary for the transmission operation of the sensory information transmission device is reached, the power supply circuit connected to the power storage element is activated, or the power storage element and the power supply circuit are connected. Characterized in that it.

In another aspect of the invention,
The power storage element is an electric double layer capacitor.
In another aspect of the invention,
The power supply circuit is a switching control system.
In another aspect of the invention,
The sensory information is visual information, and the display element that transmits the visual information is nonvolatile electronic paper that can be written and erased.

In another aspect of the invention,
An IC chip having a wireless communication function for non-contact data communication with an external reader / writer, a first coil or antenna connected thereto, and an apparatus for transmitting sensory information based on information obtained through the IC chip (Hereinafter referred to as a sensory information transmitter), the second coil or antenna for operating power of the sensory information transmitter provided separately from the first coil or antenna, and the operation of the sensory information transmitter A non-contact communication medium with a sensory information transmission function having a power storage element, and a power supply circuit and a power supply control circuit connected to the power storage element, wherein the power supply control circuit monitors the power stored in the power storage element When the power necessary for the transmission operation of the sensory information transmission device is reached, the power supply circuit connected to the power storage element is activated, or the power storage element and the power supply circuit are connected. By feeding back the output of the power supply circuit to the power supply control circuit, to operate continuously the power circuit.

  According to one aspect of the present invention, it is possible to reliably acquire sufficient power that can drive the sensory information transmission device from the external reader / writer and appropriately transmit sensory information.

It is a block diagram which shows the function structure of the non-contact communication medium 1 with an information transmission function. It is a block diagram which shows schematic structure of IC card 21 with a display function. It is a block diagram which shows the circuit structure of IC card 21 with a display function. 6 is a graph showing the characteristics of power that can be acquired by the second antenna 30.

Next, embodiments of the present invention will be described with reference to the drawings.
(Constitution)
FIG. 1 is a block diagram showing a functional configuration of a contactless communication medium 1 with an information transmission function.
As shown in FIG. 1, the non-contact communication medium 1 with an information transmission function includes a first antenna 2, an IC chip 3, a control circuit 4, a sensory information transmission device 5, a second antenna 6, a rectifier circuit 7, and a storage element. 8 includes a power supply control circuit 9 and a power supply circuit 10.
The first antenna 2 acquires a current modulated with information (hereinafter referred to as transmission information) from an AC magnetic field output from an external reader / writer. The first antenna 2 is electrically connected to the wireless communication terminal 3 a of the IC chip 3. As a result, the first antenna 2 outputs the acquired transmission information to the wireless communication terminal 3 a of the IC chip 3. As the first antenna 2, for example, a wound antenna, an etching antenna, and a printed antenna can be adopted.

The IC chip 3 acquires the transmission information output from the first antenna 2. Thus, the IC chip 3 has a wireless communication function for performing data communication in a non-contact manner with an external reader / writer. Subsequently, the IC chip 3 outputs the acquired transmission information to the control circuit 4 from the wired communication terminal 3b.
The control circuit 4 acquires transmission information output from the IC chip 3. Subsequently, the control circuit 4 outputs information to be transmitted to the user of the contactless communication medium with information transmission function 1 based on the acquired transmission information to the sensory information transmission device 5. Further, the control circuit 4 determines whether or not the sensory information transmission device 5 has completed transmission of sensory information. When the control circuit 4 determines that the transmission of the sensory information has been completed, the control circuit 4 stops the operation of supplying the power stored in the power storage element 8 to the power supply circuit 10 (hereinafter, a power supply stop signal ( (Not shown) may be output to the power supply control circuit 9. As the control circuit 4, for example, an IC (one-chip microcomputer) incorporating a CPU (Central Processing Unit), a memory circuit, and a peripheral circuit can be employed.

The sensory information transmission device 5 transmits sensory information based on information output from the control circuit 4, that is, information obtained via the IC chip 3. As sensory information, for example, visual information such as letters, auditory information such as voice, heat, and vibration can be employed. The sensory information transmitter 5 includes, for example, visual information transmitters such as light emitting diodes, liquid crystal displays, and electronic paper, auditory information transmitters that emit audible frequency sound, tactile information transmitters that generate heat and vibration, and these devices. Can be used. Specifically, the sensory information transmission device 5 includes a driver circuit (not shown) that drives the sensory information transmission device 5 based on the acquired information. The sensory information transmitter 5 transmits sensory information (visual information, auditory information, heat, vibration, etc.) based on the acquired information using a driver circuit (not shown).
In the present embodiment, an example in which the sensory information transmission device 5 includes a driver circuit (not shown) for driving the sensory information transmission device 5 has been described, but other configurations may be employed. For example, the control circuit 4 may include a driver circuit (not shown).

The second antenna 6 is a coil or antenna for operating power of the sensory information transmitter 5. Specifically, the second antenna 6 acquires AC power from an AC magnetic field output from the external reader / writer. Subsequently, the second antenna 6 outputs the acquired AC power to the rectifier circuit 7. The second antenna 6 is provided separately from the first antenna 1.
In the present embodiment (FIG. 1), an example in which coiled antennas are used as the first antenna 2 and the second antenna 6 has been described, but other configurations may be adopted. For example, a linear antenna, a coiled antenna, or the like may be appropriately employed according to the frequency of the alternating magnetic field output from the external reader / writer. Further, the frequency of the alternating magnetic field for acquiring transmission information and the frequency of the alternating magnetic field for acquiring power may be the same or different.

The rectifier circuit 7 converts AC power output from the second antenna 6 into DC power. Subsequently, the rectifier circuit 7 outputs the converted DC power to the storage element 8.
The power storage element 8 is a power storage element for operating power of the sensory information transmission device 5. Specifically, the storage element 8 stores the DC power output from the rectifier circuit 7. As the electric storage element 8, for example, a large-capacity capacitor that stores electric charge (electric power) can be adopted. An example of the large capacity capacitor is an electric double layer capacitor. The electric double layer capacitor is a capacitor composed of an activated carbon layer as a solid electrode and an electrolyte solution. When an electric voltage is applied, an electric double layer capacitor attracts negative ions to the activated carbon layer of the positive electrode, attracts positive ions to the activated carbon layer of the negative electrode, and forms an electric double layer between the activated carbon layer and the electrolyte. Use the phenomenon for power storage. Thereby, the electric double layer capacitor can obtain a capacitance more than 1000 times that of the electrolytic capacitor. Unlike the secondary battery, the electric double layer capacitor does not require a chemical reaction and has a low internal resistance. It can be charged / discharged in a short time and has a feature such as a long element life because of little deterioration due to charge / discharge. Therefore, the electric double layer capacitor is suitable as the electricity storage element 8.
In the present embodiment, an example in which a large-capacity capacitor (electric double layer capacitor) is employed as the power storage element 8 has been described. However, other configurations may be employed. For example, a secondary battery such as a lithium ion secondary battery or a nickel metal hydride battery may be adopted as the power storage element 8.

  The power supply control circuit 9 monitors the electric power stored in the power storage element 8. Subsequently, the power supply control circuit 9 determines whether or not the electric power stored in the power storage element 8 has become a set value or more. As the set value, for example, electric power necessary to drive each of the IC chip 3, the control circuit 4, and the sensory information transmission device 5 can be adopted. Specifically, it is determined whether or not the interelectrode voltage of the electricity storage element 8 (electric double layer capacitor) is equal to or higher than the interelectrode threshold voltage Vth. As the inter-electrode threshold voltage Vth, for example, an inter-electrode voltage when electric power necessary for driving each of the IC chip 3, the control circuit 4, and the sensory information transmitting device 5 is accumulated can be employed. When the power supply control circuit 9 determines that the voltage between the electrodes of the power storage element 8 is equal to or higher than the interelectrode threshold voltage Vth, the power supply control circuit 9 determines that the power stored in the power storage element 8 is equal to or higher than the set value. The power storage element 8 and the power supply circuit 10 are electrically connected. When the storage element 8 and the power supply circuit 10 are electrically connected, the power supply control circuit 9 supplies the power stored in the storage element 8 to the power supply circuit 10.

  In the present embodiment, the power supply control circuit 9 monitors the power stored in the power storage element 8, and when the power required for the start operation of the sensory information transmission device 5 is reached, the power storage element 8 and the power supply circuit 10. Although an example in which the two are electrically connected is shown, other configurations may be employed. For example, the power supply control circuit 9 may monitor the power stored in the power storage element 8 and activate the power supply circuit 10 when the power necessary for the start operation of the sensory information transmission device 5 is reached.

Here, a method of calculating the interelectrode threshold voltage Vth will be described.
The total current consumption of the IC chip 3, the control circuit 4, and the sensory information transmitter 5 required when transmitting sensory information is maintained while the minimum operating voltage of the IC chip 3, the controller 4, or the sensory information transmitter 5 is maintained. Assume that the current generated by the AC magnetic field output from the external reader / writer is Ia. In this case, the non-contact communication medium 1 with an information transmission function has a disadvantage that sensor information cannot be transmitted only with the current obtained from the external reader / writer when Ia-Im <0 (1). become. Therefore, in the present embodiment, when electric power (hereinafter referred to as necessary charge amount Qr) that can compensate for the shortage current I (= | Ia−Im |) on the left side of the above equation (1) is accumulated in the storage element 8. Then, power supply to the IC chip 3, the control circuit 4, and the sensory information transmitter 5 is started by the power supply circuit 10, and the IC chip 3, the control circuit 4, and the sensory information transmitter 5 are operated. As a result, it is possible to prevent the power supply from being disabled during transmission of sensory information.

Specifically, the necessary charge amount Qr is determined by the shortage current I (= | Ia−Im |) and the operating time t (the operating time of the IC chip 3, the control circuit 4 and the sensory information transmitter 5 required for transmitting sensory information ( For example, it is calculated by the following equation (2) based on a predetermined constant value)).
Qr [C] = I [A] × t [sec.] (2)
The amount of charge Qc stored in the storage element 8 (electric double layer capacitor) is calculated by the following equation (3) based on the interelectrode voltage Vc and the capacitance C.
Vc [V] = Qc [C] / C [F] (3)
Therefore, the interelectrode voltage Vc of the power storage element 8 when the necessary charge amount Qr is accumulated in the power storage element 8 is calculated by the following formula (4) based on the formulas (2) and (3).
Vc [V] = (I [A] × t [sec.]) / C [F] (4)
Therefore, the interelectrode threshold voltage Vth is calculated by the following equation (5) based on the above equation (4) and the minimum operating voltage Vp (for example, a predetermined constant value) of the power supply circuit 10.
Vth [V] = Vc + Vp = (I [A] × t [sec.]) / C [F] + Vp [V] (5)

In addition, even when power cannot be obtained from the AC magnetic field output from the external reader / writer during the switching of the transmission content (sensory information) of the sensory information transmission device 5, the transmission content of the sensory information transmission device 5 The inter-electrode threshold voltage Vth for supplying the power necessary to complete the switching of (sensory information) can be calculated as the current Ia = 0 based on the above equation (5).
The power supply control circuit 9 can also determine whether or not the control circuit 4 has output a power supply stop signal. When the power supply control circuit 9 determines that the control circuit 4 has output a power supply stop signal, the power supply control circuit 9 can also stop supplying the power stored in the power storage element 8 to the power supply circuit 10.

  When the power stored in the storage element 8 is supplied, the power supply circuit 10 adjusts the supplied power to a voltage suitable for the IC chip 3, the control circuit 4, and the sensory information transmitter 5. As the power supply circuit 10, for example, a series regulator power supply circuit, a shunt regulator power supply circuit, a switching control regulator power supply circuit, or the like can be adopted. Since the series regulator power supply circuit and the shunt regulator power supply circuit are step-down regulator power supply circuits, they can be used when the interelectrode threshold voltage Vth can be higher than the minimum operating voltage Vp of the power supply circuit 10. For example, the maximum chargeable voltage of the storage element 8 (electric double layer capacitor) is generally 2.5V to 3.0V. Therefore, when the interelectrode threshold voltage Vth exceeds the maximum chargeable voltage of the storage element 8 (electric double layer capacitor), the maximum chargeable voltage is obtained by connecting the storage element 8 (electric double layer capacitor) in series. It can be used by increasing the inter-electrode threshold voltage Vth. On the other hand, the switching control type regulator power supply circuit can be configured as any of a step-down type, a step-up type, and a step-up / down type regulator power supply circuit. Some switching control regulator power supply circuits generally operate from 0.3V to 1V. For this reason, it is not necessary to increase the maximum voltage that can be charged by connecting electric double layer capacitors in series, and the minimum operating voltage is also low. Therefore, compared to series regulator power supply circuits and shunt regulator power supply circuits, power storage elements It is preferable because the electric power stored in 8 (electric double layer capacitor) can be used efficiently. Further, it is more preferable because the amount of charge is smaller and the charging time can be shortened. Subsequently, the power supply circuit 10 supplies the adjusted power to each of the IC chip 3, the control circuit 4, and the sensory information transmission device 5.

(Example)
Examples of the present embodiment will be described with reference to the drawings.
In the present embodiment, an IC card 21 with a display function was created as the non-contact communication medium 1 with an information transmission function.
FIG. 2 is a configuration diagram showing a schematic configuration of the IC card 21 with a display function of the present embodiment. FIG. 2 is a configuration diagram showing an external configuration of the IC card 21 with a display function according to the present embodiment. FIG. 2B is a configuration diagram showing an internal configuration of the IC card 21 with a display function according to the present embodiment.
As shown in FIG. 2, the IC card with a display function 21 sandwiches a circuit board 22 based on a polyimide base material between a front side exterior base material 23 and a back side exterior base material 24 whose display part is transparent, The circuit board 22 was sealed with the front side exterior base material 23 and the back side exterior base material 24.

FIG. 3 is a configuration diagram showing a circuit configuration of the IC card 21 with a display function.
As shown in FIG. 3, the circuit board 22 includes a first antenna 25 and a resonance capacitor 26 (corresponding to the first antenna 2 in FIG. 1) electrically connected in parallel to the first antenna 25. 1-chip dual interface IC chip 27 (corresponding to IC chip 3 in FIG. 1), 1-chip microcontroller 28 (corresponding to control circuit 4 in FIG. 1), dot matrix display type electronic paper module having a 2.7 inch display screen 29 (corresponding to sensory information transmitter 5 in FIG. 1), second antenna 30 and resonant capacitor 31 electrically connected in parallel with second antenna 30 (corresponding to second antenna 6 in FIG. 1) , A bridge-type rectifier circuit 32 using a Schottky diode, a rectifier capacitor (not shown) (corresponding to the rectifier circuit 7 of FIG. 1), an electric double layer capacitor 3 (corresponding to the power storage element 8 in FIG. 1), the power supply control circuit main body 34 and the switch circuit 35 (corresponding to the power supply control circuit 9 in FIG. 1), and the step-up switching control regulator power supply circuit 36 (power supply circuit 10 in FIG. 1). Was implemented).

The first antenna 25 was formed of 5 turns of a copper pattern having an outer shape of 32 mm × 36 mm, a pattern width of 0.3 mm, a pattern interval of 0.2 mm, and a thickness of 18 μm. The second antenna 30 was formed of 4 turns of a copper pattern having an outer shape of 76 mm × 44 mm, a pattern width of 0.4 mm, a pattern interval of 0.2 mm, and a thickness of 18 μm. The resonance capacitors 26 and 31 were adjusted so that the first antenna 25 and the second antenna 30 resonate with an alternating magnetic field of 13.56 MHz.
When the frequency of the AC magnetic field for acquiring transmission information and the frequency of the AC magnetic field for acquiring power are different from each other, the first antenna 25 and the second antenna 30 are AC magnetic fields of each frequency. The resonance capacitors 26 and 31 are adjusted so as to resonate.

The first antenna 25 acquires a current modulated with transmission information from an AC magnetic field output from an external reader / writer. The first antenna 25 is electrically connected to the wireless communication terminals AC0 and AC1. Thereby, the first antenna 25 outputs the acquired transmission information to the wireless communication terminals AC0 and AC1 of the one-chip dual interface IC chip 27.
The 1-chip dual interface IC chip 27 acquires the transmission information output from the first antenna 25. Thus, the one-chip dual interface IC chip 27 has a wireless communication function for performing data communication with an external reader / writer in a contactless manner. Subsequently, the one-chip dual interface IC chip 27 outputs the acquired transmission information to the input terminals (SDA, SCL) of the one-chip microcontroller 28.

  The one-chip microcontroller 28 acquires information output from the one-chip dual interface IC chip 27. Subsequently, the one-chip microcontroller 28 stores information to be transmitted to the user of the IC card 21 with a display function based on the acquired transmission information in a built-in display buffer (not shown). Subsequently, the one-chip microcontroller 28 outputs information stored in a built-in display buffer (not shown) to the dot matrix display type electronic paper module 29. Further, the one-chip microcontroller 28 determines whether or not the dot matrix display type electronic paper module 29 has completed rewriting of sensory information. When the one-chip microcontroller 28 determines that the dot matrix display type electronic paper module 29 has completed the rewriting of the sensory information, the one-chip microcontroller 28 sets the output terminal OFF to the ground state (0 V) (power supply stop signal ( 0V) is output). The output terminal OFF is electrically connected to the input terminal 35 a of the switch circuit 35 via the switch disconnection signal line 37. In this embodiment, the one-chip microcontroller 28 is formed of an IC incorporating a CPU, a memory circuit, and a peripheral circuit.

  The dot matrix display type electronic paper module 29 transmits (displays) information output from the one-chip microcontroller 28, that is, information obtained via the one-chip dual interface IC chip 27 to the display element. In this embodiment, the dot matrix display type electronic paper module 29 is a non-volatile electronic paper that can be written and erased by a display element that transmits visual information. As the non-volatile electronic paper, for example, a ferroelectric liquid crystal display and an electrophoretic display can be adopted.

  The second antenna 30 is a coil or antenna for operating power of the dot matrix display type electronic paper module 29. Specifically, the second antenna 30 acquires AC power from an AC magnetic field output from the external reader / writer. Subsequently, the second antenna 30 outputs the acquired AC power to a bridge rectifier circuit 32 using a Schottky diode and a rectifier capacitor (not shown). The second antenna 30 is provided separately from the first antenna 25.

A bridge type rectifier circuit 32 and a rectifier capacitor (not shown) using a Schottky diode convert AC power output from the second antenna 30 into DC power. Subsequently, the bridge type rectifier circuit 32 using a Schottky diode and a rectifier capacitor (not shown) output the converted DC power to the electric double layer capacitor 33.
The electric double layer capacitor 33 is a storage element for operating power of the dot matrix display type electronic paper module 29. Specifically, the electric double layer capacitor 33 stores the DC power output from the bridge type rectifier circuit 32 using a Schottky diode and a rectifier capacitor (not shown). In this embodiment, the electric double layer capacitor 33 is formed with a capacitance of 50 mF and a maximum voltage of 2.75V.

  The power supply control circuit main body 34 monitors the electric power stored in the electric double layer capacitor 33. Subsequently, the power supply control circuit main body 34 determines whether or not the electric power stored in the electric double layer capacitor 33 has become a set value or more. Specifically, it is determined whether or not the interelectrode voltage of the electric double layer capacitor 33 is equal to or higher than the interelectrode threshold voltage Vth. When the power supply control circuit main body 34 determines that the interelectrode threshold voltage Vth is equal to or higher than the threshold voltage Vth, the power control circuit body 34 determines that the electric power stored in the electric double layer capacitor 33 is equal to or higher than the set value. A single pulse signal is output to the input terminal 35 a of the switch circuit 35. As a single pulse signal, for example, after changing from a low level (eg, 0 V) to a high level (eg, 1 V or more) for a predetermined time (eg, 100 msec.), The low level (eg, 0 V) again. A rectangular signal having a width of a certain time (for example, 100 msec.) Can be employed.

  The step-up switching control regulator power supply circuit 36 is supplied with the electric power stored in the electric double layer capacitor 33 when the switch circuit 35 is switched on. Here, the on state is a state in which the electric double layer capacitor 33 and the step-up switching control regulator power supply circuit 36 are electrically connected. Subsequently, the step-up switching control regulator power supply circuit 36 adjusts the supplied power to a voltage suitable for the one-chip dual interface IC chip 27, the one-chip microcontroller 28, and the dot matrix display type electronic paper module 29. Subsequently, the step-up switching control regulator power supply circuit 36 supplies the adjusted power to each of the one-chip dual interface IC chip 27, the one-chip microcontroller 28, and the dot matrix display type electronic paper module 29 via the output terminal 36a. Supply. The output terminal 36 a of the step-up switching control regulator power supply circuit 36 is electrically connected to the input terminal 35 a of the switch circuit 35 via a diode 39. As a result, the output of the step-up switching control regulator power supply circuit 36 is fed back to the input terminal 35 a of the switch circuit 35.

  The switch circuit 35 determines whether or not the input terminal 35a of the switch circuit 35 is at a high level (for example, 1 V or more). When the switch circuit 35 determines that the voltage at the input terminal 35a is at a high level (eg, 1 V or more), the switch circuit 35 turns on the electric double layer capacitor 33 and the step-up switching control regulator power supply circuit 36. Switched to an electrically connected state). Here, the output voltage via the diode 38 of the power supply control circuit body 34, the output voltage via the diode 39 of the step-up switching control regulator power supply circuit 36, and the one-chip micro are connected to the input terminal 35a of the switch circuit 35. A combined voltage with the output voltage of the controller 28 is input. On the other hand, when the switch circuit 35 determines that the voltage of the input terminal 35a of the switch circuit 35 is at a low level (for example, 0 V), the switch circuit 35 is switched to an off state. The off state is a state in which the electric double layer capacitor 33 and the step-up switching control regulator power supply circuit 36 are electrically disconnected.

  Thus, when the power supply control circuit main body 34 outputs a single pulse signal, the switch circuit 35 determines that the input terminal 35a of the switch circuit 35 is at a high level (for example, 1 V or more), and is in an on state, that is, The state is switched to a state where the double layer capacitor 33 and the step-up switching control system regulator power supply circuit 36 are electrically connected. When switched to the ON state, the switch circuit 35 supplies the power stored in the electric double layer capacitor 33 to the step-up switching control regulator power supply circuit 36. Further, when power is supplied, the step-up switching control regulator power supply circuit 36 starts supply to the one-chip dual interface IC chip 27, the one-chip microcontroller 28, and the dot matrix display type electronic paper module 29.

  Further, after the switch circuit 35 is turned on, until the voltage between the electrodes of the electric double layer capacitor 33 becomes less than the minimum operating voltage of the step-up switching control regulator power supply circuit 36 or the input of the switch circuit 35 The output of the step-up switching control regulator power supply circuit 36 is fed back through the diode 39 until the voltage at the terminal 35a becomes low level (for example, 0V), so that the input terminal 35a of the switch circuit 35 becomes high. It is determined that the level (for example, 1 V or more), and the ON state, that is, the state where the electric double layer capacitor 33 and the step-up switching control system regulator power supply circuit 36 are electrically connected is continued. Thereby, the step-up switching control system regulator power supply circuit 36 is continuously operated. Therefore, after the switch circuit 35 is turned on, at least the output of the step-up switching control regulator power supply circuit 36 is fed back through the diode 39, and the input terminal 35a of the switch circuit 35 is at a high level (for example, 1 V or more). It is only necessary to maintain the high level (for example, 1 V or more) of the single pulse signal output from the power supply control circuit main body 34 until it is determined as follows. In this embodiment, the time of the high level (for example, 1 V or more) of the single pulse signal output from the power supply control circuit main body 34 is set to 100 msec.

  Further, when the one-chip microcontroller 28 outputs the power supply stop signal (0 V) (when the output terminal OFF is set to the ground state (0 V)) while the ON state continues, the switch circuit 35 is in the OFF state, that is, the switch It is determined that the input terminal 35a of the circuit 35 is at a low level (for example, 0 V), and the electric double layer capacitor 33 and the step-up switching control regulator power supply circuit 36 are switched to a state where they are electrically disconnected. When the switch is turned off, the switch circuit 35 stops supplying the electric power stored in the electric double layer capacitor 33 to the boosting switching control regulator power supply circuit 36. When the supply of power is stopped, the step-up switching control regulator power supply circuit 36 supplies the supplied power to the one-chip dual interface IC chip 27, the one-chip microcontroller 28, and the dot matrix display type electronic paper module 29. Stop supplying.

  Further, a constant voltage stabilizing circuit 40 is further mounted on the circuit board 22 between the bridge type rectifier circuit 32 and the electric double layer capacitor 33. The constant voltage stabilization circuit 40 sets the voltage (for example, 13V) of the output of the bridge type rectifier circuit 32 to be equal to or lower than the maximum voltage (2.75V) of the electric double layer capacitor 33. The constant voltage stabilization circuit 40 may be omitted when the output voltage of the bridge rectifier circuit 32 is equal to or lower than the maximum voltage of the electric double layer capacitor 33.

  Further, the constant voltage stabilization circuit 40 has a function (for example, a variable resistor) that limits the current flowing from the bridge type rectifier circuit 32 to the electric double layer capacitor 33 to a set value or less when charging of the electric double layer capacitor 33 is started. . As a result, the constant voltage stabilization circuit 40 causes the second antenna 30 (electric double layer capacitor 33) to be short-circuited at the initial charging stage of the electric double layer capacitor 33, and obtains transmission information by the first antenna 25. The possibility of affecting (wireless communication) can be reduced, and wireless communication can be performed stably from the beginning of charging.

  In the present embodiment, the power control circuit body 34 monitors the power stored in the electric double layer capacitor 33, and when the power required for the transmission operation of the dot matrix display type electronic paper module 29 is reached, the switch Although the example in which the circuit 35 electrically connects the electric double layer capacitor 33 and the step-up switching control regulator power supply circuit 36 has been described, other configurations may be employed. For example, the switch circuit 35 is omitted, and the power supply control circuit main body 34 monitors the power stored in the power storage element 8, and when the power necessary for the transmission operation of the sensory information transmission device 5 is reached, It is good also as a structure to start.

(Operation)
Next, the operation of the IC card 21 with a display function of this embodiment will be described.
First, it is assumed that the IC card 21 with a display function is held over an external reader / writer and enters an AC magnetic field output from the external reader / writer. Then, the second antenna 30 acquires AC power from the AC magnetic field output from the external reader / writer. Subsequently, the bridge-type rectifier circuit 32 and the rectifier capacitor (not shown) convert the AC power acquired by the second antenna 30 into DC power. Subsequently, the electric double layer capacitor 33 accumulates (charges) the DC power converted by the bridge type rectifier circuit 32 and the rectifier capacitor (not shown).

  Assume that charging of the electric double layer capacitor 33 proceeds, the voltage between the electrodes of the electric double layer capacitor 33 increases, and the voltage between the electrodes of the electric double layer capacitor 33 becomes equal to or higher than the threshold voltage Vth between electrodes. Then, the power supply control circuit main body 34 determines that the voltage between the electrodes of the electric double layer capacitor 33 is equal to or higher than the threshold voltage Vth between electrodes, and outputs a single pulse signal to the input terminal 35a of the switch circuit 35 via the diode 38. To do. As a result, the switch circuit 35 is switched to the ON state, and the electric double layer capacitor 33 and the step-up switching control system regulator power supply circuit 36 are electrically connected. Then, supply of the electric power stored in the electric double layer capacitor 33 to the step-up switching control regulator power supply circuit 36 is started. Subsequently, the step-up switching control system regulator power supply circuit 36 adjusts the supplied power to a voltage suitable for the one-chip dual interface IC chip 27, the one-chip microcontroller 28, and the dot matrix display type electronic paper module 29. For example, the voltage is boosted to a predetermined set voltage (for example, 3 V). Then, the step-up switching control regulator power supply circuit 36 supplies the adjusted power to each of the one-chip dual interface IC chip 27, the one-chip microcontroller 28, and the dot matrix display type electronic paper module 29. Here, the output terminal 36 a of the step-up switching control regulator power supply circuit 36 is electrically connected to the input terminal 35 a of the switch circuit 35 via a diode 39. As a result, the step-up switching control regulator power supply circuit 36 also supplies the power whose voltage has been adjusted to the input terminal 35 a of the switch circuit 35. As a result, the switch circuit 35 continues to be in the ON state, and the connection state between the electric double layer capacitor 33 and the step-up switching control system regulator power supply circuit 36 is continued. Then, the supply of the electric power stored in the electric double layer capacitor 33 to the step-up switching control regulator power supply circuit 36 is continued. As described above, the step-up switching control system regulator power supply circuit 36 is continuously operated. The electric double layer capacitor 33 continues to store DC power from the second antenna 30 even after the electric double layer capacitor 33 and the step-up switching control regulator power supply circuit 36 are connected.

  Further, the first antenna 25 acquires a current modulated with transmission information from an AC magnetic field output from an external reader / writer. Subsequently, the one-chip dual interface IC chip 27 acquires transmission information from the modulated current acquired by the first antenna 25. Subsequently, the 1-chip microcontroller 28 stores information to be transmitted to the user of the IC card 21 with a display function based on the transmission information acquired by the 1-chip dual interface IC chip 27 in a built-in display buffer (not shown). . Subsequently, the one-chip microcontroller 28 outputs the information stored in the built-in display buffer to the driver IC 29 a of the dot matrix display type electronic paper module 29. Subsequently, the driver IC 29a drives the electronic paper element of the dot matrix display type electronic paper module 29 based on the output information. Thereby, the dot matrix display type electronic paper module 29 rewrites the display content (sensory information).

  Further, it is assumed that the dot matrix display type electronic paper module 29 has completed the rewriting of display contents (sensory information). Then, the one-chip microcontroller 28 determines that the display content (sensory information) of the dot matrix display type electronic paper module 29 has been rewritten, and sets the input terminal 35a of the switch circuit 35 to the ground state (0 V). As a result, the switch circuit 35 switches to the OFF state, and the electric double layer capacitor 33 and the step-up switching control system regulator power supply circuit 36 are electrically disconnected. Then, the supply of the electric power stored in the electric double layer capacitor 33 to the step-up switching control regulator power supply circuit 36 is stopped. Therefore, electric power can remain in the electric double layer capacitor 33 and the charging time can be shortened when the electric double layer capacitor 33 is charged next time.

FIG. 4 is a graph showing characteristics of power that can be acquired by the second antenna 30.
In the IC card 21 with a display function of this embodiment, the power required for rewriting the display contents (sensory information) of the dot matrix display type electronic paper module 29 was 3 V, 15 mA, and the time required was 3 seconds. However, as shown in FIG. 4, the electric power that can be acquired by the second antenna 30 is up to 14 mA when the voltage is 3V. If the current is 15 mA, the voltage is up to 2.1V. Therefore, in the IC card with display function 21 of this embodiment, only the power that can be acquired from the second antenna 30 is the power required for rewriting the display content (sensory information) of the dot matrix display type electronic paper module 29. 3V, 15mA cannot be obtained. On the other hand, in this embodiment, if it is determined that the DC power stored in the electric double layer capacitor 33 has become equal to or higher than the set value, the DC power stored in the electric double layer capacitor 33 is converted to a one-chip dual interface IC chip. 27, a one-chip microcontroller 28, and a dot matrix display type electronic paper module 29 can be supplied. Thereby, in the present embodiment, sufficient power that can drive the dot matrix display type electronic paper module 29 can be reliably acquired from the external reader / writer and the sensory information can be appropriately transmitted. In addition, from the above equation (5), even when power cannot be obtained from the alternating magnetic field output from the external reader / writer during the switching of the transmission content (sensory information) of the sensory information transmitter 5, The inter-electrode threshold voltage Vth for supplying the power of 3 V and 15 mA required for completing the rewriting of the display contents of the matrix display type electronic paper module 29 for 3 seconds is the change of the step-up switching control regulator power supply circuit 36. If the efficiency is 75% and the minimum operating voltage is 1V, it becomes 2.2V.

  In the present embodiment, the IC chip 3 in FIG. 1 and the one-chip dual interface IC chip 27 in FIG. 3 constitute an IC chip. Similarly, the first antenna 2 in FIG. 1 and the first antenna 25 in FIG. 3 constitute a first coil or antenna. 1 and the dot matrix display type electronic paper module 29 of FIG. 3 constitute a sensory information transmitter. Further, the second antenna 6 in FIG. 1 and the second antenna 30 in FIG. 3 constitute a second coil or antenna. Moreover, the electrical storage element 8 of FIG. 1 and the electric double layer capacitor 33 of FIG. 3 constitute an electrical storage element. Further, the power supply circuit 10 of FIG. 1 and the step-up switching control regulator power supply circuit 36 of FIG. 3 constitute a power supply circuit. Further, the power control circuit 9 in FIG. 1, the power control circuit main body 34, and the switch circuit 35 in FIG. 3 constitute a power control circuit.

(Effect of this embodiment)
The present embodiment has the following effects.
(1) When the power supply control circuit main body 34 monitors the power stored in the electric double layer capacitor 33 and reaches the power required for the transmission operation of the dot matrix display type electronic paper module 29, the switch circuit 35 The electric double layer capacitor 33 and the step-up switching control system regulator power supply circuit 36 are electrically connected. Alternatively, when the power control circuit body 34 monitors the power stored in the electric double layer capacitor 33 and reaches the power required for the transmission operation of the dot matrix display type electronic paper module 29, it is connected to the electric double layer capacitor. The boosting switching control system regulator power supply circuit 36 is started.
According to such a configuration, it is possible to reliably acquire sufficient power that can drive the dot matrix display type electronic paper module 29 from an external reader / writer and appropriately transmit sensory information.

(2) In this example, the electric double layer capacitor 33 was used as the power storage element.
According to such a configuration, the capacitance of the power storage element can be increased, and the internal resistance of the power storage element can be reduced. Therefore, for example, electrical energy can be stored in a relatively short time. Therefore, the time for holding the IC card 21 with a display function over the external rewriting device can be shortened.
(3) In this embodiment, the dot matrix display type electronic paper module 29 is used.
According to such a configuration, no power is required except during display switching, so that the DC power stored in the electric double layer capacitor 33 can be used efficiently.

(4) In this embodiment, the step-up switching control regulator power supply circuit 36 is used.
According to such a configuration, the minimum operating voltage can be lowered, so that the DC power stored in the electric double layer capacitor 33 can be used efficiently.
(5) The switch circuit 35 monitors the electric power stored in the electric double layer capacitor 33, and when the electric power required for the transmission operation of the dot matrix display type electronic paper module 29 is reached, the electric double layer capacitor 33 and the voltage booster Type switching control regulator power supply circuit 36 is electrically connected, and the output of boosting switching control regulator power supply circuit 36 is fed back to switch circuit 35 so that boosting switching control regulator power supply circuit 36 continues. The DC power stored in the electric double layer capacitor 33 is continuously supplied.
According to such a configuration, since the feedback is directly fed from the output of the step-up switching control type regulator power supply circuit 36 without using the one-chip microcontroller 28 that requires a reset operation when the power supply is turned on, high-speed control is possible.

2 First antenna (first coil or antenna)
3 IC chip (IC chip)
5 Sensory information transmitter (sensory information transmitter)
6 Second antenna (second coil or antenna)
8 Electric storage element (electric storage element)
9 Power control circuit (Power control circuit)
10 Power supply circuit (Power supply circuit)
25 First antenna (first coil or antenna)
27 One-chip dual interface IC chip (IC chip)
29. Dot matrix display type electronic paper module (sensory information transmitter)
30 Second antenna (second coil or antenna)
33 Electric double layer capacitor (storage element)
34 Power control circuit body (Power control circuit)
35 Switch circuit (Power control circuit)
36 Step-up switching control regulator power supply circuit (power supply circuit)

Claims (5)

An IC chip having a wireless communication function for performing data communication with an external reader / writer in a contactless manner;
A first coil or antenna connected to it;
A device for transmitting sensory information based on information obtained via the IC chip (hereinafter referred to as sensory information transmitter);
A second coil or antenna for operating power of the sensory information transmitter provided separately from the first coil or antenna;
A non-contact communication medium with a sensory information transmission function having a storage element for operating power of the sensory information transmission device, and a power supply circuit and a power supply control circuit connected thereto,
The power supply control circuit monitors the electric power stored in the power storage element and activates the power supply circuit connected to the power storage element when the power necessary for the transmission operation of the sensory information transmission device is reached, or A non-contact communication medium with a sensory information transmission function, wherein the power storage element and the power supply circuit are connected.   The contactless communication medium with sensory information transmission function according to claim 1, wherein the power storage element is an electric double layer capacitor.   The contactless communication medium with sensory information transmission function according to claim 1, wherein the power supply circuit is a switching control system.   4. The sensory information transmitting function-provided feature according to claim 1, wherein the sensory information is visual information, and the display element that transmits the visual information is nonvolatile electronic paper that can be written and erased. Contact communication medium. An IC chip having a wireless communication function for performing data communication with an external reader / writer in a contactless manner;
A first coil or antenna connected to it;
A device for transmitting sensory information based on information obtained via the IC chip (hereinafter referred to as sensory information transmitter);
A second coil or antenna for operating power of the sensory information transmitter provided separately from the first coil or antenna;
A non-contact communication medium with a sensory information transmission function having a storage element for operating power of the sensory information transmission device, and a power supply circuit and a power supply control circuit connected thereto,
The power supply control circuit monitors the electric power stored in the power storage element and activates the power supply circuit connected to the power storage element when the power necessary for the transmission operation of the sensory information transmission device is reached; or A power supply circuit control method for continuously operating the power supply circuit by connecting the power storage element and the power supply circuit and feeding back the output of the power supply circuit to the power supply control circuit.

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