JP7351919B2 - RFID tag - Google Patents

Description

The present disclosure relates to an RFID tag having a power generation section.

Japanese Unexamined Patent Publication No. 2002-65418 discloses an RFID tag that includes a solar cell and a display device. The display of this RFID tag on a display device is updated by rewriting the information on the RFID tag using a reader/writer.

In an RFID tag that includes a power generation section such as a solar cell and a functional section such as a display device, the operation stops when the generated power falls below the lower limit of the operating power of the functional section. Even if an RFID tag is equipped with a storage battery to avoid operation stoppage, it is difficult to install a large-capacity storage battery into an RFID tag.

(1)
The RFID tag of one aspect of the present disclosure includes:
The power generation section,
a functional unit and an RFID IC that are driven based on the electric power generated by the power generation unit;
a power storage unit capable of storing power generated by the power generation unit;
Equipped with
The functional unit includes a control unit,
The control unit includes:
The first processing for controlling the functional unit is divided into a plurality of processing sequences, and during execution of the first processing, the plurality of processing sequences are performed based on the amount of charge of the power storage unit and the amount of power consumed by the functional unit. calculating one or more of the processing sequences in which the amount of charge of the power storage unit does not fall below a lower limit;
After executing the calculated processing sequence, the first processing is interrupted and a transition is made to a low power consumption mode .
(2)
An RFID tag according to another aspect of the present disclosure includes:
The power generation section,
a functional unit and an RFID IC that are driven based on the electric power generated by the power generation unit;
a power storage unit capable of storing power generated by the power generation unit;
Equipped with
The functional unit includes a control unit,
The control unit includes:
performing an estimation process for estimating the power generated by the power generation unit during a period in which the first process for controlling the functional unit is not executed;
During execution of the first process, it is determined whether or not to interrupt the first process based on the amount of charge of the power storage unit and the amount of power consumed by the functional unit, and the prediction process is performed to determine whether or not to interrupt the first process. A length of time for interrupting the first process is determined based on the generated power.

FIG. 1 is an exploded perspective view showing an RFID tag according to Embodiment 1 of the present disclosure. FIG. 2 is a block diagram showing the internal configuration of the RFID tag of Embodiment 1. FIG. 5 is a time chart illustrating an example of the operation of the RFID tag according to the first embodiment. 3 is a flowchart showing a procedure of display control processing executed by a control unit. 5 is an explanatory diagram showing an example of a change in an image due to the display control process of FIG. 4. FIG. FIG. 5 is an explanatory diagram showing an example of the display control process in FIG. 4; FIG. 5 is an explanatory diagram showing a modification of the display control process in FIG. 4; FIG. 2 is a block diagram showing the internal configuration of an RFID tag according to Embodiment 2 of the present disclosure. 7 is a flowchart illustrating a procedure of display control processing executed by a control unit of Embodiment 2. FIG. 7 is a flowchart showing the procedure of _PL3 interrupt processing executed by the control unit of the second embodiment. 7 is a flowchart showing the procedure of _PL1 interrupt processing executed by the control unit of the second embodiment. 7 is a time chart illustrating display control processing according to the second embodiment. FIG. 3 is a block diagram showing the internal configuration of an RFID tag according to a third embodiment. 12 is a flowchart showing the procedure of a generated power calculation process executed by a control unit of Embodiment 3. 5 is a time chart illustrating the operation of a power supply control section in a low power consumption mode. 12 is a flowchart showing a procedure of display control processing executed by a control unit of Embodiment 3. 15 is a time chart illustrating the display control process of FIG. 14. FIG.

Hereinafter, each embodiment of the present disclosure will be described in detail with reference to the drawings.

(Embodiment 1)
FIG. 1 is an exploded perspective view showing an RFID tag according to Embodiment 1 of the present disclosure. FIG. 2 is a block diagram showing the internal configuration of the RFID tag of the first embodiment.

As shown in FIG. 1, the RFID tag 1 of Embodiment 1 of the present disclosure includes power generation units 31 and 32, a display unit 33, a circuit board 20, a housing 10, and a lid 40. The housing 10 accommodates the power generation units 31 and 32, the display unit 33, and the circuit board 20. The lid 40 closes the opening of the housing 10. The power generation units 31 and 32 are photovoltaic panels that generate power by receiving light from the outside, and are arranged facing the transparent window of the lid 40. Note that the power generation units 31 and 32 are not limited to photovoltaic panels, and may be energy harvesters that generate power by absorbing energy such as heat or vibration from the external environment. The display section 33 is, for example, a liquid crystal display panel, and is arranged to face the transmission window of the lid 40.

Further, as shown in FIG. 2, the RFID tag 1 includes a power control unit (for example, PMIC: Power Management Integrated Circuit) 21, a first power IC (Integrated Circuit) 22, a second power IC 23, and a control unit 24. , an RFID IC 25, and a power storage unit 27. These are mounted on the circuit board 20. The circuit board 20 may have an antenna for the RFID IC 25. The display unit 33 and the control unit 24 correspond to an example of a functional unit according to the present disclosure.

The power supply control unit 21 receives power from the power generation units 31 and 32, and sends the received power to the power storage unit 27, the first power supply IC 22, and the second power supply IC 23. The distribution of power to the power storage unit 27, the first power supply IC 22, and the second power supply IC 23 changes as appropriate depending on the amount of charge of the power storage unit 27 and the power used by the first power supply IC 22 and the second power supply IC 23. The power supply control unit 21 includes a switch SW that connects or disconnects a power line that transmits power from the power generation units 31 and 32, and a monitoring unit 21a that monitors the voltage of the power storage unit 27 and switches the switch SW.

Power storage unit 27 is, for example, a capacitor. When a capacitor is employed, the voltage changes depending on the amount of charge, so the amount of charge may be read as voltage. Power storage unit 27 may be a small capacity secondary battery.

The first power supply IC 22 converts the power received from the power supply control section 21 into a control voltage and supplies it to the control section 24 . This voltage may be supplied to the RFID IC 25. The second power supply IC 23 converts the power received from the power supply control unit 21 into a voltage for display driving, and supplies the voltage to the display unit 33 . The drive voltage of the display section 33 may be higher than the drive voltage of the control section 24, and in this case, the display drive voltage is higher than the control voltage.

The RFID IC 25 performs wireless communication with the reader/writer using, for example, UHF (Ultra High Frequency) band radio waves. The RFID IC 25 has a data storage section that can read and write information from a reader/writer, and a storage section that stores identification information. Information to be output to the display section 33 can be written in the data storage section.

The control unit 24 is an integrated circuit that includes a ROM (Read Only Memory) that stores a control program and control data, a CPU (Central Processing Unit) that executes the control program, and a RAM (Random Access Memory). Based on the fact that the display information of the RFID IC 25 has been updated, the control unit 24 reads display information from the RFID IC 25, generates display image data from the read information, and displays the image data on the display unit. 33 (corresponding to the first process according to the present disclosure). The display content of the display unit 33 is updated by the drawing process. Further, during the drawing process, the control unit 24 estimates the difference between the amount of charge of the power storage unit 27 and the amount of power consumed by the control unit 24 and the display unit 33. This difference corresponds to the remaining charge of power storage unit 27 after power consumption. Then, the control section 24 switches the operation mode of the control section 24 itself according to the estimated difference. The control unit 24 can shift between a normal mode and a low power consumption mode in which the power consumption of the RFID tag 1 is reduced. The normal mode is an operation mode in which high-load processing is continuously executed. The low power consumption mode is an operation mode in which the power consumption of the control unit 24 (or the control unit 24 and the display unit 33) is reduced by interrupting or terminating high-load processing. In this embodiment, the drawing process corresponds to the above-mentioned high-load processing. In the normal mode, the operating clock of the control unit 24 is set to the normal first speed, and in the low power consumption mode, the operating clock of the control unit 24 is set to a speed lower than the first speed, so that the power consumption is lower than that of the normal mode. However, the power consumption in the low power consumption mode may be further reduced.

<Overview of power control>
FIG. 3 is a time chart illustrating an example of the operation of the RFID tag of the first embodiment. FIG. 3 shows the operation when the power generated by the power generation units 31 and 32 is close to the lower limit value at which the operation of the RFID tag 1 is guaranteed (hereinafter referred to as the "operation guaranteed lower limit value").

In the RFID tag 1, a plurality of levels P _L1 , P _L2 , and P _L3 are set for the amount of charge of the power storage unit 27 . The plurality of levels are a first level P _L1 where the voltage of the power storage unit 27 reaches the upper limit voltage, a second level P _L2 where the voltage of the power storage unit 27 reaches the charging restart voltage, and a level where the voltage of the power storage unit 27 reaches the display unit 33 and and a third level _PL3 that reaches the operating lower limit voltage that realizes normal operation of the control unit 24.

First, an overview of the operation during the display maintenance period T2 without display update will be explained. Period T2 is a period of low power consumption mode. The power generation units 31 and 32 change the generated power according to the external environment. Even if the generated power of the power generation units 31 and 32 is at the lower limit value for which operation is guaranteed, the display on the display unit 33 is only maintained, and during period T2 when the control unit 24 is in the low power consumption mode, the generated power is exceeds power consumption. Therefore, the monitoring unit 21a of the power supply control unit 21 turns on the switch SW, and the power storage unit 27 takes in the generated power, so that the amount of charge of the power storage unit 27 increases.

On the other hand, in period T2, when the amount of charge in the power storage unit 27 reaches the first level P _L1 , the power storage unit 27 reaches the upper limit voltage, so the monitoring unit 21a of the power supply control unit 21 turns off the switch SW and reduces the generated power. Stop importing. Note that the off control of the switch SW is similarly executed in other periods. When the intake of generated power is stopped, the power of power storage unit 27 is slightly consumed, and the amount of charge decreases. Then, when the amount of charge in the power storage unit 27 reaches the second level _PL2 , the monitoring unit 21a turns on the switch SW again to take in the generated power. Under such control by the monitoring unit 21a, the amount of charge of the power storage unit 27 is maintained between the first level P _L1 and the second level P _L2 during the period T2 when power consumption is low. In addition, even when the state shifts to low power consumption mode with a low charge amount, as at the beginning of period T2, the charge amount returns to the second level P _L2 or higher within a certain period of time due to the intake of generated power. . In FIG. 3, period T1 is also a period of low power consumption mode, and the same control as period T2 is performed in period T1 as well.

Next, an overview of the operations during the display update periods T11 to T13, T21, and T22 will be explained. Assume that at timing t1 in FIG. 3, display information is written from the reader/writer to the RFID IC 25. Based on the update of the display information, the control unit 24 executes a drawing process to update the display on the display unit 33. As shown in periods T11, T12, and T13, when the power generated by the power generation units 31 and 32 is at the lower limit value with guaranteed operation, when the control unit 24 executes the drawing process, the power consumption of the control unit 24 and the display unit 33 decreases. far exceeds the generated power. Therefore, during periods T11, T12, and T13, even if the generated power is taken in, the amount of charge in power storage unit 27 decreases.

The content displayed on the display unit 33 includes a plurality of image elements (see FIG. 5), and the drawing process includes individual drawing processes that sequentially draw the plurality of image elements. Therefore, the drawing process can be divided into a plurality of processing sequences, for example, by dividing each image element into drawings. A processing sequence refers to a series of multiple processing steps for rendering one image element.

When executing a plurality of processing sequences of the drawing process, the control unit 24 estimates the difference between the amount of charge of the power storage unit 27 and the power consumption of the drawing process. Then, from the estimation result, the control unit 24 determines one or more processing sequences in which the amount of charge of the power storage unit 27 does not fall below the third level _PL3 , and executes the determined processing sequence (period T11). After completing the processing sequence, the control unit 24 temporarily shifts to the low power consumption mode by interrupting the drawing process (period T21). After waiting for the amount of charge to recover, the control unit 24 restarts the drawing process again. By repeating such a procedure, the control unit 24 completes all processing sequences necessary for display updating. In FIG. 3, periods T11 to T13 indicate the execution period of the processing sequence, and periods T21 and T22 indicate the period of the low power consumption mode.

The drawing process of the control unit 24 as described above is realized by the display control process described below. Through the display control processing, even when the power generated by the power generation units 31 and 32 is low, the control unit 24 can update the display without causing the display unit 33 and the control unit 24 to stop operating.

<Display control processing>
FIG. 4 is a flowchart showing the procedure of display control processing executed by the control unit. FIG. 5 is an explanatory diagram showing an example of a change in an image due to display control processing. The processes in the periods T11, T21, T12, T22, and T13 in FIG. 3 described above are realized by the display control process in FIG. 4.

As shown in FIG. 5, the display image E includes a plurality of display elements e1 to e6 separated by a plurality of frames or rows. The plurality of display elements e1 to e6 include text image display elements e1 to e4, which have a small amount of data and low power consumption for drawing processing, and display elements e1 to e4 for text images, which have a relatively large amount of data and moderate power consumption for drawing processing. The display element e5 includes a display element e5, and a display element e6 of the second code image, which has a large amount of data and consumes a large amount of power for drawing processing. The control unit 24 divides the series of drawing processes into processing sequences for each display element e1 to e6, and executes the divided processing sequences in order. In the flowchart of FIG. 4, processing sequence n is processing for displaying the n-th display element en (n is any one of 1 to 6), power consumption p _n is power consumption of processing sequence n, and P _n is It means the integrated value of power consumption from the start or restart of display updating to the n-th display element en.

When display information is written to the RFID IC 25, the control unit 24 starts the display control process shown in FIG. 4. When the display control process is started, first, the control unit 24 initializes variables n and _P0 to be used by an initialization process (step S1). The variable n indicates the serial number of the divided processing sequence, and _P0 indicates the initial value of the integrated value of power consumption.

Next, the control unit 24 moves the process to a loop process of steps S2 to S8. The loop process is repeatedly executed for the number of display elements e1 to e6 while updating the variable n (=1 to 6). In the loop process, first, the control unit 24 calculates the power consumption p _n of the processing sequence n of the display element en (step S2). The control unit 24 has in advance the power consumption required to display the text image, the power consumption required to display the first code image, and the power consumption required to display the second code image as control data, and uses these to control the power consumption. , calculate the power consumption p _n of the processing sequence n. The control unit 24 has control data (function or data table) that calculates power consumption that changes depending on the number of characters and font size of a text image, and uses this control data to correspond to display elements e1 to e4 of the text image. The power consumption amounts p ₁ to p ₄ may be calculated. Furthermore, the control unit 24 has control data (a function or a data table) for calculating the amount of power consumption that changes depending on the size of the image for the display elements e5 and e6 of the first code image and the second code image. , the power consumption amounts p ₅ and p ₆ corresponding to the display elements e5 and e6 of the code image may be calculated using this control data.

Subsequently, the control unit 24 calculates an integrated value P _n of the power consumption p _n up to the display element en (step S3). Then, the control unit 24 compares the integrated value P _n with the amount of power (P _L1 - P _L3 ) that can be supplied from the power storage unit 27 (step S4). The process in step S4 is a process for estimating whether the difference between the amount of power consumption (integrated value P _n ) required for the drawing process and the amount of charge (P _L1 ) of the power storage unit 27 is less than the third level P _L3 . Equivalent to. As a result of the comparison, if the integrated value Pn is smaller, the control unit 24 executes a processing sequence n for displaying the display element en (step S5). In step S5, the display element en is output to the display section 33. Then, the control unit 24 adds 1 to the variable n (step S6), determines whether the drawing process has been completed for all display elements (step S7), and if it has completed, shifts to the low power consumption mode. (Step S11), the display control process is ended, but if it has not been done yet, the process returns to step S2.

On the other hand, as a result of the comparison in step S4, if the integrated value _Pn is larger, the control unit 24 shifts to the low power consumption mode (step S8), waits for a predetermined time (T seconds) (step S9), The previous integrated value P _n-1 is updated to zero (step S10), and the process returns to step S2. In the next round of the loop processing (steps S2 to S4, S8 to S10), since the integrated value P _n-1 is updated to zero, the integrated value P _n calculated in step S3 is the integrated value from zero. becomes. The standby time (T seconds) in step S8 corresponds to the time required for the amount of charge in power storage unit 27 to return from third level _PL3 to first level _PL1 or second level _PL2 when the amount of power generation is at the lower limit.

In the display control process of FIG. 4, transition to the low power consumption mode in step S8 means transition to a process (step S9) in which the process sequence n for displaying the above-mentioned display elements is interrupted for a waiting period. . Furthermore, the transition to the low power consumption mode in step S11 means transition to an operation mode in which the above processing sequence n is not executed upon completion of the display process. By interrupting or terminating the above processing sequence n, the power consumption of the control unit 24 is reduced. Note that if the control unit 24 has a function of reducing power consumption by lowering the operating clock speed, the control unit 24 may activate the above function in steps S8 and S11. In this case, if the process moves to step S1 or step S2 while the above function is being executed, the control unit 24 cancels the above function.

FIG. 6 is an explanatory diagram showing an example of display control processing.

According to the display control process described above, as shown in FIG. 5, the process sequence of the drawing process is executed in the order of the first display element e1 to the sixth display element e6, and the display control process is completed. Display steps J1 to J4 in FIG. 5 are executed during processing periods T31 to T34 in FIG. 6, respectively. To explain with focus on the processing period T31, during the period T31, the control unit 24 calculates the electric power amounts p ₁ to p ₄ necessary for displaying the display elements e1 to e4 and their integrated value P ₁ (=p ₁ ). ~P ₄ (=p ₁ +p ₂ +p ₃ +p ₄ ) is calculated. Then, the control unit 24 determines whether the amount of charge in the power storage unit 27 does not fall below the lower limit third level P _L3 due to the power consumption of the integrated values P ₁ to P ₄ , and controls the display elements e 1 to e 3 to the extent that it does not fall below the lower limit third level P L3. Execute the processing sequence. If the power amount p ₄ for the fourth display element e4 is added, the integrated value P ₄ falls below the third level P _L3 , so the processing sequence for the fourth display element e4 is not executed during the processing period T31. After executing the processing sequence, the control unit 24 temporarily interrupts display updating to enter the low power consumption mode, and charges the power storage unit 27 through the standby time T. Then, the amount of charge in power storage unit 27 increases to near the first level _PL1 . Thereafter, the control unit 24 similarly proceeds with the drawing processing of the subsequent display elements e4 to e6. Control that takes into account the difference between the amount of power consumption and the amount of charge in the power storage unit 27 is realized by the display control process shown in _FIG. , the display of all display elements e1 to e6 can be updated.

As described above, according to the RFID tag 1 of the first embodiment, the control unit 24 calculates the difference between the amount of charge of the power storage unit 27 and the amount of power consumed by the control unit 24 itself and the display unit 33 in the drawing process. guess. Then, the control unit 24 controls itself based on the difference estimation result. For example, the number of consecutively executed processing sequences is limited so that the difference obtained by subtracting the power consumption from the amount of charge accumulated up to the first level P _L1 does not fall below the lower limit of the third level P _L3 , and then, Transition to low power consumption mode by interrupting drawing processing. Therefore, even when the amount of power generation is low, it is possible to prevent the control unit 24 and the display unit 33 from deviating from normal operation and stopping during the drawing process.

Furthermore, according to the RFID tag 1 of the first embodiment, the time period during which the control unit 24 interrupts the drawing process and shifts to the low power consumption mode is set to a certain period of time. According to such a setting, even if the generated power is at the lower limit value for which operation is guaranteed, the amount of charge can be restored to a predetermined level. Therefore, even if the generated power is low, it is possible to prevent the control unit 24 and the display unit 33 from deviating from normal operation due to a decrease in power.

(Modified example)
FIG. 7 is an explanatory diagram showing a modification of the display control process.

In the display control process of the first embodiment, the standby time T for restoring the amount of charge in the power storage unit 27 is constant (see FIG. 6). However, the amount of power required to recover the charge amount (the amount of consumed power) is determined by the type of display image (text image, first code image, second code image) and the number of display images, for example, the number of display images. Determined according to the amount of data. In the modified example, the control unit 24 estimates the power consumption used in the drawing process when shifting to the low power consumption mode, and even if the power generation amount is at the lower limit value, the control unit 24 estimates the power consumption used in the drawing process. The standby times T41, T42, and T43 that allow charging equivalent to the amount are determined. Then, the control unit 24 shifts to the low power consumption mode for the determined standby time (T41 to T43).

According to the modified example, the interruption time of the drawing process can be shortened compared to the first embodiment, so there is an advantage that the drawing process can be completed in a short time. Furthermore, since the time at which the control unit 24 interrupts the drawing process and shifts to the low power consumption mode is set to a time corresponding to the processing sequence executed immediately before, the generated power is guaranteed to operate during the interruption period. Even if it is at the lower limit, the amount of charge can be restored to a predetermined level. Therefore, even if the generated power is low, it is possible to prevent the control unit 24 and the display unit 33 from deviating from normal operation due to a decrease in power.

(Embodiment 2)
FIG. 8 is a block diagram showing the internal configuration of the RFID tag of the second embodiment. In the second embodiment, an interrupt generation circuit 29 that generates interrupt signals S _L3 and S _L1 by comparing the voltage of the power storage unit 27 and the reference voltages V _L3 and V _L1 is added from the configuration of the first embodiment. There is. Furthermore, in the second embodiment, the configuration of the control unit 24A and the procedure of display control processing are changed from those in the first embodiment. The interrupt generation circuit 29 corresponds to an example of a detection unit according to the present disclosure.

The interrupt generation circuit 29 includes a comparator 29a that compares the voltage of the power storage unit 27 and a reference voltage V _L3 (corresponding to the second threshold), and a comparator 29a that compares the voltage of the power storage unit 27 and the reference voltage V _L1 (corresponds to the first threshold). and a comparator 29b for comparing. Reference voltage V _L3 corresponds to a voltage at which the amount of charge in power storage unit 27 reaches third level P _L3 . Comparator 29a outputs an interrupt signal _{S_L3} when the voltage of power storage unit 27 is lower than reference voltage _{V_L3} . The reference voltage V _L1 corresponds to a voltage at which the amount of charge of the power storage unit 27 becomes the first level P _L1 . Comparator 29b outputs an interrupt signal S _L1 when the voltage of power storage unit 27 is higher than reference voltage V _L1 . Detection that the voltage of power storage unit 27 has reached reference voltages V _L3 and V _L1 corresponds to detection that the amount of charge of power storage unit 27 has reached the lower limit value and that it has reached the upper limit value, respectively.

The control unit 24A has interrupt terminals Ia and Ib, and receives interrupt signals S _L3 and S _L1 , respectively. Based on the input of the interrupt signals S _L3 and S _L1 to the interrupt terminals Ia and Ib, the control unit 24A can realize control based on the amount of charge of the power storage unit 27 and the amount of power consumed in the drawing process.

FIG. 9A is a flowchart showing the procedure of display control processing executed by the control unit of the second embodiment. FIG. 9B is a flowchart showing the procedure of _PL3 interrupt processing executed by the control unit of the second embodiment. FIG. 9C is a flowchart showing the procedure of _PL1 interrupt processing executed by the control unit of the second embodiment. In the second embodiment, when display information is written to the RFID IC 25 and display control processing is started, the control unit 24A first sets interrupt permission as shown in FIG. 9A (step S21). . Next, the control unit 24A sequentially executes a processing sequence of a drawing process for updating the display content of the display unit 33 according to the display information written in the RFID IC 25 (step S22). When all processing sequences are completed, the control unit 24A sets interrupt prohibition (step S23), shifts to low power consumption mode (step S24), and ends the display control process. The operation mode in which drawing processing is not executed from the end of one display control process until the next display control process is started corresponds to the low power consumption mode of step S24.

Due to the interrupt permission setting in step S21, during the drawing process in step S22, the control unit 24A starts P _L3 interrupt processing when the interrupt signal S _L3 is input, and when the interrupt signal S _L1 is input. and starts _PL1 interrupt processing.

When the P _L3 interrupt processing is started, as shown in FIG. 9B, the control unit 24A checks the interrupted point of the processing sequence in step S22, determines which processing sequence should be restarted from when restarting, and sets the restart position. is stored, and the drawing process in step S22 is interrupted (step S25). The control unit 24A then shifts to the low power consumption mode (step S26) and ends the _PL3 interrupt process. The operation mode in which the drawing process is interrupted corresponds to the low power consumption mode in step S26. Due to the transition to the low power consumption mode in step S26, the operating clock of the control unit 24A may be slowed down.

When the P _L1 interrupt process is started, as shown in FIG. 9C, the control unit 24A returns from the low power consumption mode to the normal mode (step S27). Then, the control unit 24A reads the restart position stored in step S25 of the _PL3 interrupt process, and restarts the processing sequence of the drawing process of step S22 from the restart position (step S28). The operation mode in which the drawing process is executed by restarting may mean returning to the normal mode in step S27. Further, by returning to the normal mode in step S27, the operating clock of the control section 24A may return to the normal speed. After finishing the P _L1 interrupt process, the control unit 24A returns the process to the drawing process and continues the drawing process from the middle of step S22.

FIG. 10 is a time chart illustrating display control processing according to the second embodiment. In the second embodiment as well, in display updating, a plurality of display elements e1, e2, . . . included in a display image are sequentially subjected to drawing processing. When the display control process is started at timing t41 and the control unit 24A performs the drawing process (display update) of the display elements e1 and e2, the electric power amounts p ₁ and p ₂ for these processes are taken out from the power storage unit 27 and stored in the power storage unit 27. The amount of charge in the section 27 decreases. Then, when the amount of charge reaches the third level P _L3 (timing t42), the interrupt signal S _L3 is input to the control unit 24A, and the drawing process (display update) is interrupted, so that the control unit 24A mode, and the amount of charge in power storage unit 27 is restored (period T43). Then, when the amount of charge in the power storage unit 27 reaches the first level P _L1 (timing t44), the interrupt signal S _L1 is input to the control unit 24A, and the interrupted drawing process is restarted. For example, the drawing process is restarted from the middle of the interrupted display element e2. If there are many display elements, such interruption and restart will be repeated. Then, when the drawing process for the last display element e3 is completed (timing t45), the control unit 24A ends the drawing process and shifts to the low power consumption mode. With such control, all the drawing processing can be performed without the voltage of the power storage unit 27 falling below the operating lower limit voltage.

As described above, the RFID tag 1A of the second embodiment includes the interrupt generation circuit 29 that detects that the voltage of the power storage unit 27 reaches the reference voltages V _L1 and V _L3 . Then, the control unit 24 switches between transitioning to the low power consumption mode (interrupting display updating) and returning to normal mode (resuming display updating) based on the interrupt signals S _L1 and S _L3 . Therefore, even when the generated power is low, it is possible to prevent the amount of charge in the power storage unit 27 from falling below the third level _PL3 during the drawing process, thereby preventing the control unit 24 and the display unit 33 from deviating from normal operation. Furthermore, in the second embodiment, since the time during which the control unit 24 is in the low power consumption mode can be suppressed to the necessary minimum, the processing for updating the display (all drawing processing) can be completed promptly according to the magnitude of the generated power. can.

(Embodiment 3)
FIG. 11 is a block diagram showing the internal configuration of the RFID tag according to the third embodiment. In the third embodiment, a part of the procedure of display control processing by the control unit 24B is changed from the first embodiment. Furthermore, in the third embodiment, a configuration is added in which the switch control signal Scsw of the monitoring section 21a is input from the power supply control section 21 to the control section 24B. In the third embodiment, when the control unit 24B transitions to the low power consumption mode during the drawing process, the duration of the low power consumption mode is determined according to the power generation status of the power generation units 31 and 32. Different from form 1.

FIG. 12 is a flowchart showing the procedure of the generated power calculation process executed by the control unit of the third embodiment. FIG. 13 is a time chart illustrating the operation of the power supply control section in the low power consumption mode.

The control unit 24B executes the generated power calculation process of FIG. 12 during the low power consumption mode. In the generated power calculation process, the control unit 24B first sets the variables m, C _ON , and C _OFF to be used to initial values through an initialization process (step S31). m is a variable indicating the number of times of loop processing, C _ON is a variable by which the ON state of the switch SW is counted, and C _OFF is a variable by which the OFF state of the switch SW is counted.

Next, the control unit 24B proceeds to processing for sampling the signal level of the switch control signal Scsw (loop processing of steps S32 to S37). In the loop process, first, the control unit 24B determines whether the switch control signal Scsw is at a high level or a low level (step S32). If the level is high, the control unit 24B determines that the switch SW is on, and adds +1 to the variable C _ON (step S33). On the other hand, if the level is low, the control unit 24B determines that the switch SW is in the off state, and adds +1 to the variable C _OFF (step S34).

Next, the control unit 24B waits for a predetermined time (X seconds) (step S35), adds +1 to the variable m (step S36), determines whether the variable m exceeds the specified number of times (step S37), and adds 1 to the specified number of times (step S37). If not, the process returns to step S32. The above predetermined time (X seconds) may be, for example, a short time on the order of milliseconds or one second or less. On the other hand, if the predetermined number of times has been exceeded, the control unit 24B exits the loop processing S32 to S37 and estimates the generated power P _GEN (step S38). Then, the generated power calculation process ends.

As shown in FIG. 13, in the low power consumption mode, the power consumption is very small, so the switch SW of the power supply control unit 21 is turned on and off in a relatively long cycle. Here, if the generated power of the power generation units 31 and 32 is large, the stored power amount quickly reaches the upper limit first level P _L1 from the second level P _L2 , so the on period of the switch SW becomes shorter. On the other hand, if the generated power of the power generation units 31 and 32 is small, it will take a long time for the stored power amount to reach the first level P _L1 from the second level P _L2 , so the on period of the switch SW becomes longer. Furthermore, in the low power consumption mode, the power consumption is constant regardless of the generated power, so one off period of the switch SW is approximately constant. Therefore, by comparing the on period and the off period of the switch SW, the power generated by the power generation units 31 and 32 can be estimated.

In the generated power calculation process, the value of the switch control signal Scsw is sampled at appropriate sampling intervals through the loop process of steps S32 to S37 in FIG. 12, and the ratio between the on period and the off period of the switch SW is determined. Then, in step S33, the control unit 24B can estimate the generated power P _GEN of the power generation units 31 and 32 from the ratio of the on period and the off period of the switch SW.

The execution timing of the generated power calculation process may be scheduled during the low power consumption mode so that the generated power calculation process is executed for each period in which the generated power does not change significantly.

Also in the third embodiment, the control unit 24B starts the display control process (FIG. 14) based on the writing of display information in the RFID IC 25. The execution time of the drawing process is relatively short, and the power generated by the power generation units 31 and 32 rarely fluctuates greatly during this time. Therefore, the power generated during the drawing process can be considered to be approximately equal to the value calculated in the last generated power calculation process executed in the low power consumption mode.

FIG. 14 is a flowchart showing the procedure of display control processing executed by the control unit of the third embodiment. FIG. 15 is a time chart illustrating display control processing according to the third embodiment. The display control process of the third embodiment is characterized in that the standby time TX (T51, T52, T53: FIG. 15) after transition to the low power consumption mode is determined by taking into consideration the power generated by the power generation units 31 and 32. This is different from Embodiment 1. Steps similar to those in the display control process of Embodiment 1 are given the same reference numerals and detailed explanations will be omitted.

If the comparison result in step S4 is NO, the control unit 24B transitions to the low power consumption mode by interrupting the execution of the processing sequence n in step S5 (step S41), and also sets the charging time in consideration of the generated power. The calculation process is executed (step S42). Here, the control unit 24B employs the value of the generated power P _GEN calculated in the last generated power calculation process as the generated power, and uses the previous display element em (m= The integrated value P _n-1 calculated for P n-1) is adopted. Then, the control unit 24B calculates the time TX=P _n-1 /P _GEN required to cover the integrated value P _n-1 of the consumed power amount with the generated power P _GEN , and calculates the calculated time. Let charging time be TX. After that, the control unit 24B waits for the time TX calculated in step S42 (step S43), and returns to step S2 after the waiting time TX has elapsed.

With such a method of determining the standby time TX, as shown in FIG. 15, the transition times T51, T52, and T53 to the low power consumption mode during display control processing are determined by the integrated values P _X1 , P of the power consumption at that time. It is adjusted based on _X2 , _PX3 , and the generated power of the power generation units 31 and 32. By adjusting the standby time, the amount of charge in the power storage unit 27 almost reaches or is close to the upper limit first level P _L1 at the timing when the standby times T51, T52, and T53 have elapsed. Therefore, in a situation where the generated power is high, the standby times T51, T52, and T53 are adjusted as appropriate in response to the situation, and the time required to perform the display control process can be shortened.

As described above, according to the RFID tag 1B of the third embodiment, the control unit 24B estimates the power generated by the power generation units 31 and 32, and based on the estimation results, the time T51, T52, and T52 for transitioning to the low power consumption mode. Determine T53. Therefore, the time of the low power consumption mode can be changed depending on the generated power, and it is possible to prevent the interruption period during display control processing from becoming unnecessarily long.

Furthermore, according to the RFID tag 1B of the third embodiment, the control unit 24B estimates the generated power based on the switch control signal Scsw of the power supply control unit 21 and the ratio of the connection time and disconnection time of the switch SW. Therefore, a large amount of power is not consumed to estimate the generated power, and even if the control unit 24B slows down the operating clock during the low power consumption mode, the process of estimating the generated power can be performed. Furthermore, the generated power can be accurately estimated with a simple circuit configuration.

The embodiments of the present disclosure have been described above. However, the RFID tag of the present disclosure is not limited to the above embodiments. For example, in the embodiment described above, the display section and the control section are shown as functional sections driven by the generated electric power. However, the functional unit may include various devices such as a light emitting unit, an audio output unit, and a sensor unit that performs various detections. Further, in the embodiment described above, an example is shown in which the low power consumption mode is an operation mode in which drawing processing is not executed. However, the low power consumption mode is not limited to the above-mentioned operation modes, and may be any operation mode as long as it is an operation mode in which the power consumption of the functional unit is lower than in the normal mode. Further, in the above embodiment, an example was shown in which the normal mode is an operation mode in which drawing processing is continuously executed, but in the normal mode, the power consumption of the functional unit is higher than in the low power consumption mode. Any operation mode may be used as long as it is an operation mode. Other details shown in the embodiments can be changed as appropriate without departing from the spirit of the invention.

The present disclosure can be used in an RFID tag having a power generation section.

1, 1A, 1B RFID tag 20 Circuit board 21 Power supply control section 21a Monitoring section SW Switch Scsw Switch control signal 22 First power supply IC
23 Second power supply IC
24, 24A, 24B Control unit 25 RFID IC
27 Power storage section 29 Interrupt generation circuit 29a, 29b Comparator Ia, Ib Interrupt terminal S _L1 , S _L3 interrupt signal V _L1 , V _L3 reference voltage 31, 32 Power generation section 33 Display section P _L1 first level P _L2 second Level P _L3 3rd level E Display image e1 to e6 Display element p ₁ to p ₆ Electric energy

Claims (4)

The power generation section,
a functional unit and an RFID IC that are driven based on the electric power generated by the power generation unit;
a power storage unit capable of storing power generated by the power generation unit;
Equipped with
The functional unit includes a control unit,
The control unit includes:
The first processing for controlling the functional unit is divided into a plurality of processing sequences, and during execution of the first processing, the plurality of processing sequences are performed based on the amount of charge of the power storage unit and the amount of power consumed by the functional unit. calculating one or more of the processing sequences in which the amount of charge of the power storage unit does not fall below a lower limit;
After executing the calculated processing sequence, interrupting the first processing and transitioning to a low power consumption mode;
RFID tag. The power generation section,
a functional unit and an RFID IC that are driven based on the electric power generated by the power generation unit;
a power storage unit capable of storing power generated by the power generation unit;
Equipped with
The functional unit includes a control unit,
The control unit includes:
performing an estimation process for estimating the power generated by the power generation unit during a period in which the first process for controlling the functional unit is not executed;
During execution of the first process, it is determined whether or not to interrupt the first process based on the amount of charge of the power storage unit and the amount of power consumed by the functional unit, and the prediction process is performed to determine whether or not to interrupt the first process. determining a length of time for interrupting the first process based on the generated power;
RFID tag. The time length for interrupting the first process is a fixed time or a time according to the process sequence,
RFID tag according to claim 1 . Further comprising a switch that connects or disconnects a power line that transmits power from the power generation unit to the power storage unit,
The control unit estimates the generated power based on a ratio between a connection time and a disconnection time of the switch.
RFID tag according to claim 2 .

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