JP4149381B2 - Power charging circuit - Google Patents

Description

  The present invention relates to a power charging circuit that charges a capacitor by rectifying a modulation signal.

  For example, when a non-contact IC tag such as an RFID tag is not equipped with a power source such as a battery, for example, when a modulation signal such as a pulse signal transmitted from a power supply device such as a reader / writer device is received, A power charging circuit that rectifies the modulation signal and charges the capacitor is mounted.

In a conventional power charging circuit, a pair of diodes and a pair of capacitors are connected in parallel, and when the pair of diodes performs full-wave rectification on the modulation signal, the pair of capacitors charges the rectified current from the pair of diodes ( For example, refer nonpatent literature 1).
A non-contact IC tag such as an RFID tag uses a charge accumulated in a capacitor of a power charging circuit as a power source, and performs demodulation processing of a modulation signal that is data.

MWE2003 Microwave Workshop Digest “Ultra-small RFID chip: Muchip” by Mitsuo Usami Hitachi, Ltd. Central Research Laboratories, 2003, pp. 235-238

  Since the conventional power charging circuit is configured as described above, when the distance to the power supply device that transmits the modulated signal is short, the received power of the modulated signal is large, and a sufficient accumulated voltage of the capacitor can be obtained. However, if the distance to the power supply device that transmits the modulated signal is increased, the received power of the modulated signal is reduced, so the accumulated voltage of the capacitor is reduced, and the demodulation circuit of a non-contact IC tag such as an RFID tag is driven. There were problems such as being unable to do so.

  The present invention has been made to solve the above-described problems, and provides a power charging circuit capable of obtaining a large accumulated voltage of a capacitor even when a distance to a power supply device that transmits a modulation signal is long. With the goal.

  The power charging circuit according to the present invention connects the first diode via the impedance element and the input side of the pair of diodes, and connects the second diode via the impedance element and the output side of the pair of diodes, A plurality of charging capacitors are connected between the input side of the first diode and the output side of the second diode.

  According to the present invention, the first diode is connected to the input side of the pair of diodes via the impedance element, and the second diode is connected to the output side of the pair of diodes via the impedance element. Since a plurality of charging capacitors are connected between the input side of the diode and the output side of the second diode, the accumulated voltage of the large capacitor can be increased even if the distance to the power supply device that transmits the modulation signal is long. There is an effect that can be obtained.

Embodiment 1 FIG.
FIG. 1 is a configuration diagram showing an RFID tag equipped with a power charging circuit according to Embodiment 1 of the present invention. In particular, FIG. 1 (a) is a top view of the RFID tag, (b) is a cross-sectional view of the RFID tag, (C) is a bottom view of the RFID tag.
In the figure, an antenna 1 receives a modulation signal (hereinafter referred to as an RF signal) such as a pulse signal transmitted from a power supply device such as a reader / writer device, and a feeding point 2 is provided substantially at the center. Yes.
In the RFID tag, dielectric substrates 3a and 3b and a ground conductor 4 are laminated, and a through hole 5 is provided from the feeding point 2 of the antenna 1 toward the lower surface. The power charging circuit 7 is mounted on the lower surface of the RFID tag. The power charging circuit 7 is connected from the feeding point 2 of the antenna 1 through the through hole 5 and the microstrip line 6 (for example, the line resistance of the microstrip line 6 is 50Ω). The RF signal received by the antenna 1 is input.

2 is a block diagram showing a power charging circuit according to Embodiment 1 of the present invention. In the figure, an RF signal input terminal 11 is a terminal for inputting an RF signal received by the antenna 1. The diodes 12 and 13 constitute a pair of diodes that rectify the RF signal when the RF signal is input from the connection point 14.
One end of the resistor 15 which is an impedance element is connected to the input side of the diode 12 and has a resistance value R ₁ greater than the input impedance Z ₀ at the RF signal input terminal 11. The diode 16 as the first diode has an output side connected to the other end of the resistor 15 and rectifies the RF signal together with the diodes 12, 13, and 19.
A short-circuit capacitor 17 that is a first short-circuit capacitor is connected between the output side of the diode 16 and the connection point 14 of the diodes 12 and 13.

One end of the resistor 18 that is an impedance element is connected to the output side of the diode 13, and has a resistance value R ₁ that is greater than the input impedance Z ₀ at the RF signal input terminal 11. The diode 19 as the second diode has an input side connected to the other end of the resistor 18 and rectifies the RF signal together with the diodes 12, 13, and 16.
A short-circuit capacitor 20 which is a second short-circuit capacitor is connected between the input side of the diode 19 and the connection point 14 of the diodes 12 and 13.

Charging capacitors 21 and 22, which are first charging capacitors, are connected in series with each other, and the connection point 27 is connected to the ground in terms of high frequency. The pair of charging capacitors 21 and 22 are connected in parallel with the pair of diodes 12 and 13 and charge the rectified current by the diodes 12, 13, 16 and 19.
A charging capacitor 23, which is a second charging capacitor, is connected between the input side of the diode 12 and the input side of the diode 16, and charges a rectified current by the diodes 12, 13, 16, and 19.
A charging capacitor 24, which is a third charging capacitor, is connected between the output side of the diode 13 and the output side of the diode 19, and charges the rectified current from the diodes 12, 13, 16, and 19.
The output voltage terminals 25 and 26 are terminals for outputting the accumulated voltage of the charging capacitors 21 to 24.

Next, the operation will be described.
For example, when a power supply device such as a reader / writer device transmits and receives data to and from an RFID tag, when an RF signal is transmitted to supply power to the RFID tag, the antenna 1 of the RFID tag receives the RF signal.
The RF signal is input from the feeding point 2 of the antenna 1 to the RF signal input terminal 11 of the power charging circuit 7 through the through hole 5 and the microstrip line 6.

  When an RF signal is input from the RF signal input terminal 11 of the power charging circuit 7, the diodes 12, 13, 16, and 19 rectify the RF signal, so that a rectified current flows in the direction indicated by the arrow in FIG. Electric charges are accumulated in the capacitors 21 to 24.

  At this time, the diodes 16 and 19 and the charging capacitors 23 and 24 are not provided, and the power charging circuit 7 operates as the diodes 12 and 13 and the charging capacitors 21 and 22 (in this case, the charging capacitors 21 and 22 also serve as short-circuit capacitors). 3) (refer to FIG. 3: equivalent to the conventional example), depending on the received power of the RF signal, + V and −V are applied to the output voltage terminals 25 and 26 as the accumulated voltage of the charging capacitors 21 and 22, respectively. A voltage is applied.

  However, in the first embodiment, the diodes 16 and 19 and the charging capacitors 23 and 24 are mounted on the power charging circuit 7, and the charging capacitors 21 to 24 having the same capacity (for example, 1 pF) are stacked. Therefore, voltages of +2 V and -2 V are applied to the output voltage terminals 25 and 26 as the accumulated voltage of the charging capacitors 21 to 24, respectively.

  The demodulation circuit of the RFID tag or the like can receive voltages of + 2V and −2V from the output voltage terminals 25 and 26 when the electric charge stored in the charging capacitors 21 to 24 of the power charging circuit 7 is used as a power source. Therefore, even if the distance to the power supply device that transmits the RF signal is long and the received power of the RF signal is small, the voltage sufficient to drive is received. The possibility that it can be increased.

  As apparent from the above, according to the first embodiment, the diode 16 is connected to the input side of the diode 12 via the resistor 15, and the diode 19 is connected to the output side of the diode 13 via the resistor 18. Since the charging capacitors 21 to 24 are connected between the input side of the diode 16 and the output side of the diode 19, the output voltage terminal 25, even if the distance to the power supply device that transmits the RF signal is long. 26 produces an effect that a large voltage can be output.

  In the first embodiment, the rectified current flows through the path of diode 16 → diode 12 → diode 13 → diode 19 → charging capacitor 24 → charging capacitor 22 → charging capacitor 21 → charging capacitor 23. Although the resistors 15 and 18 are mounted as impedance elements, as shown in FIG. 4, even if the coils 31 and 32 are mounted as impedance elements, a rectified current can be passed through the same path.

In the first embodiment, the charging capacitors 21 and 22 are connected in parallel with the pair of diodes 12 and 13, but the capacitance value is half that of the charging capacitors 21 and 22, as shown in FIG. Only one charging capacitor 33 may be connected.
In this case, however, the input side of the diode 16 and the output side of the diode 19 need to be grounded at high frequency.

Embodiment 2. FIG.
In the first embodiment, the case where the four charging capacitors 21 to 24 are stacked is shown, but 2 × (N + 1) charging capacitors may be stacked. However, N = 1, 2, 3,.
For example, when six charging capacitors are stacked, as shown in FIG. 6, voltages of +3 V and -3 V are applied to the output voltage terminals 25 and 26 as the accumulated voltages of the six charging capacitors. .

Embodiment 3 FIG.
7 is a block diagram showing a power charging circuit according to Embodiment 3 of the present invention. In the figure, the same reference numerals as those in FIG.
The short-circuit capacitors 41 and 42 which are the third short-circuit capacitors are connected in series with each other, and the connection point 27 is connected to the ground in a high frequency manner. The pair of short-circuit capacitors 41 and 42 are connected in parallel with the pair of diodes 12 and 13.
A short-circuit capacitor 43 as a fourth short-circuit capacitor is connected between the input side of the diode 12 and the input side of the diode 16.
A short-circuit capacitor 44 that is a fifth short-circuit capacitor is connected between the output side of the diode 13 and the output side of the diode 19.
The charging capacitor 45 is connected between the input side of the diode 16 and the output side of the diode 19, and charges a rectified current by the diodes 12, 13, 16, and 19.

Next, the operation will be described.
For example, when a power supply device such as a reader / writer device transmits and receives data to and from an RFID tag, when an RF signal is transmitted to supply power to the RFID tag, the antenna 1 of the RFID tag receives the RF signal.
The RF signal is input from the feeding point 2 of the antenna 1 to the RF signal input terminal 11 of the power charging circuit 7 through the through hole 5 and the microstrip line 6.

When an RF signal is input from the RF signal input terminal 11 of the power charging circuit 7, the diodes 12, 13, 16, and 19 rectify the RF signal, so that a rectified current flows in the direction indicated by the arrow in FIG. Charge is accumulated in the capacitor 45.
In the third embodiment, since the short-circuit capacitors 41 to 44 are not for short-circuiting but for short-circuiting, a capacitor having a smaller capacitance value than the charging capacitors 21 to 24 in the first embodiment may be used.

  At this time, since the charging capacitor 45 having the same capacity as the total capacity of the charging capacitors 21 to 24 in FIG. 2 is mounted on the power charging circuit 7, the accumulation of the charging capacitor 45 is the same as in the first embodiment. Voltages of + 2V and −2V are applied to the output voltage terminals 25 and 26 as voltages.

  Since the demodulation circuit of the RFID tag or the like can receive voltages of + 2V and −2V from the output voltage terminals 25 and 26 when using the electric charge stored in the charging capacitor 45 of the power charging circuit 7 as a power source, Even if the distance to the power supply device that transmits the RF signal is long and the reception power of the RF signal is small, the possibility that a voltage sufficient for driving can be received increases.

  As apparent from the above, according to the third embodiment, the diode 16 is connected to the input side of the diode 12 via the resistor 15 and the diode 19 is connected to the output side of the diode 13 via the resistor 18. Since the charging capacitor 45 is connected between the input side of the diode 16 and the output side of the diode 19, the output voltage terminals 25 and 26 can be connected even if the distance to the power supply device that transmits the RF signal is long. There is an effect that a large voltage can be output.

  In the third embodiment, resistors 15 and 18 are mounted as impedance elements so that the rectified current flows through the path of diode 16 → diode 12 → diode 13 → diode 19 → charging capacitor 45. As shown in FIG. 8, even if the coils 31 and 32 are mounted as impedance elements, the rectified current can be passed through the same path.

In the third embodiment, the short-circuit capacitors 41 and 42 are connected in parallel with the pair of diodes 12 and 13, but the capacitance value is half that of the short-circuit capacitors 41 and 42 as shown in FIG. Only one short-circuit capacitor 46 may be connected.
In this case, however, the input side of the diode 16 and the output side of the diode 19 need to be grounded at high frequency.

Embodiment 4 FIG.
In the third embodiment, the case where the charging capacitor 45 having the same capacity as the total capacity of the four charging capacitors 21 to 24 in FIG. 2 is mounted is shown. However, 2 × (N + 1) charging capacitors are shown. A charging capacitor 45 having the same capacity as the total capacity may be mounted. However, N = 1, 2, 3,.
For example, when a charging capacitor 45 having the same capacity as the total capacity of six charging capacitors is mounted, the output voltage terminals 25 and 26 have + 3V as the accumulated voltage of the charging capacitor 45 as shown in FIG. , −3V is applied.

Embodiment 5. FIG.
Although not particularly mentioned in the third embodiment, as shown in FIG. 11, the integrated circuit 8 is configured by forming a part except for the charging capacitor 45 into an IC, and the charging capacitor 45 is included in the integrated circuit 8. May be externally attached.
As a result, the integrated circuit 8 can be reduced in size.

Embodiment 6 FIG.
In the first to fifth embodiments, the output voltage terminals 25 and 26 output the accumulated voltage of the charging capacitor. However, as shown in FIGS. 12 and 13, the output voltages are output from the output voltage terminals 25 and 26. A limiter 51 that restricts an increase in the output voltage may be connected between the output voltage terminal 25 and the output voltage terminal 26 so that the output voltage does not exceed a reference voltage (for example, 3 V).

  Accordingly, the limiter 51 prevents the voltage output from the output voltage terminals 25 and 26 from exceeding the reference voltage even if the distance to the power supply device that transmits the RF signal is short and the reception power of the RF signal is too large. Restricts the increase of the output voltage, so that the device such as a diode can be prevented from being damaged.

Embodiment 7 FIG.
In the sixth embodiment, the limiter 51 is connected between the output voltage terminal 25 and the output voltage terminal 26. However, as shown in FIGS. 14 and 15, the voltages output from the output voltage terminals 25 and 26 are shown. May be connected to the connection point 14 of the diodes 12 and 13 so as not to exceed the reference voltage (for example, 3V).

Accordingly, the limiter 51 prevents the voltage output from the output voltage terminals 25 and 26 from exceeding the reference voltage even if the distance to the power supply device that transmits the RF signal is short and the reception power of the RF signal is too large. Restricts the rise of the output voltage, that is, the limiter 51 limits the amplitude of the RF signal so that the amplitude of the RF signal does not exceed the reference amplitude, so that damage to a device such as a diode can be prevented. There is an effect.
Needless to say, both the limiter 51 and the limiter 52 may be mounted.

Embodiment 8 FIG.
In the sixth embodiment, the limiter 51 is connected between the output voltage terminal 25 and the output voltage terminal 26. However, as shown in FIGS. 16 and 17, the SW control circuit 61 has the output voltage terminals 25, 26. Is monitored, and when the voltage exceeds a reference voltage (for example, 3 V), the switch 62 is opened so that the diodes 12, 13, 16, 19 and the charging capacitors 21-24, 45 are disconnected. Also good.
As a result, similar to the sixth embodiment, there is an effect that damage to devices such as diodes can be prevented.

Embodiment 9 FIG.
In the eighth embodiment, the SW control circuit 61 monitors the voltage output from the output voltage terminals 25 and 26, and when the voltage exceeds a reference voltage (for example, 3V), the switch 62 is opened and the diodes 12, 13 are opened. , 16 and 19 and the charging capacitors 21 to 24 and 45 are separated from each other. However, when the limiters 51 and 52 are mounted (see FIGS. 12 to 15), the SW control circuit 61 includes the limiters 51 and 52. It is also possible to monitor whether or not current flows through the limiters 51 and 52, and when the current flows through the limiters 51 and 52, the switch 62 is opened to disconnect the diodes 12, 13, 16, and 19 from the charging capacitors 21 to 24 and 45. Good.
As a result, similar to the above-described eighth embodiment, there is an effect that damage to devices such as diodes can be prevented.

Embodiment 10 FIG.
In Embodiment 1 described above, the feeding point 2 is provided at approximately the center of the antenna 1, but as shown in FIG. 18, as the feeding point 2 is provided at the end of the antenna 1, input impedance _{Z 0} at the RF signal input terminal 11 is increased.
As the input impedance Z _{0 at the} RF signal input terminal 11 is larger, the rectified current by the diodes 12, 13, 16, and 19 is increased. The voltage can be increased.

Therefore, in the tenth embodiment, as shown in FIG. 19, a feeding point 2 is provided in the vicinity of the end of the antenna 1, and an RF signal is transmitted from the feeding point 2 via the through hole 5 and the microstrip line 6. The signal is input to the RF signal input terminal 11 of the charging circuit 7.
Thereby, since the distance to the power supply device that transmits the RF signal is long, there is an effect that a large voltage can be output from the output voltage terminals 25 and 26 even when the reception power of the RF signal is small.

  In the tenth embodiment, the RF signal is input to the RF signal input terminal 11 of the power charging circuit 7 from the feed point 2 of the antenna 1 through the through hole 5 and the microstrip line 6. As shown in FIG. 20, the RF signal is input to the RF signal input terminal 11 of the power charging circuit 7 from the feeding point 2 of the antenna 1 only through the through hole 5 without passing through the microstrip line 6. Also good.

In the tenth embodiment, the power charging circuit 7 is mounted on the lower surface of the RFID tag. However, as shown in FIG. 21, the power charging circuit 7 is mounted on the upper surface of the RFID tag. Also good.
However, in this case, since the feeding point 2 is provided at the end of the antenna 1, when the input impedance Z _{0 at} the RF signal input terminal 11 becomes too large, as shown in FIG. What is necessary is just to give 1a and to provide the feed point 2 in the notch part 1a.

Embodiment 11 FIG.
In the first to tenth embodiments, the components of the diodes 12, 13, 16, and 19 are not mentioned. For example, when a high barrier potential diode made of silicon and platinum is used, the diodes 12, 13 are used. , 16, 19 is reduced, and charging efficiency for charging capacitors 21-24, 45 is reduced.

Therefore, in the eleventh embodiment, low-barrier potential diodes made of silicon and titanium silicide are used as the diodes 12, 13, 16, 19 and the diodes 12, 13, 16, 19 are used. The flowing rectified current is increased.
As a result, according to the eleventh embodiment, the charging efficiency for the charging capacitors 21 to 24 and 45 is improved, and the distance to the power supply device that transmits the RF signal is long, so the received power of the RF signal is small. Even in this case, there is an effect that a large voltage can be output from the output voltage terminals 25 and 26.

It is a block diagram which shows the RFID tag carrying the electric power charging circuit by Embodiment 1 of this invention. It is a block diagram which shows the electric power charging circuit by Embodiment 1 of this invention. It is a block diagram which shows the electric power charging circuit which consists of a pair of diode and a pair of capacitor for charge. It is a block diagram which shows the other electric power charging circuit by Embodiment 1 of this invention. It is a block diagram which shows the other electric power charging circuit by Embodiment 1 of this invention. It is a block diagram which shows the electric power charging circuit by Embodiment 2 of this invention. It is a block diagram which shows the electric power charging circuit by Embodiment 3 of this invention. It is a block diagram which shows the other electric power charging circuit by Embodiment 3 of this invention. It is a block diagram which shows the other electric power charging circuit by Embodiment 3 of this invention. It is a block diagram which shows the electric power charging circuit by Embodiment 4 of this invention. It is a block diagram which shows the electric power charging circuit by Embodiment 5 of this invention. It is a block diagram which shows the electric power charging circuit by Embodiment 6 of this invention. It is a block diagram which shows the electric power charging circuit by Embodiment 6 of this invention. It is a block diagram which shows the electric power charging circuit by Embodiment 7 of this invention. It is a block diagram which shows the electric power charging circuit by Embodiment 7 of this invention. It is a block diagram which shows the electric power charging circuit by Embodiment 8 of this invention. It is a block diagram which shows the electric power charging circuit by Embodiment 8 of this invention. It is a block diagram which shows the electric power charging circuit by Embodiment 10 of this invention. It is a block diagram which shows the electric power charging circuit by Embodiment 10 of this invention. It is a block diagram which shows the electric power charging circuit by Embodiment 10 of this invention. It is a block diagram which shows the electric power charging circuit by Embodiment 10 of this invention. It is a block diagram which shows the electric power charging circuit by Embodiment 10 of this invention.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 Antenna, 2 Feeding point, 3a, 3b Dielectric board | substrate, 4 Ground conductor, 5 Through hole, 6 Microstrip line, 7 Power charging circuit, 8 Integrated circuit, 11 RF signal input terminal, 12, 13 Diode (a pair of diodes) ), 14 connection point, 15 resistance (impedance element), 16 diode (first diode), 17 short-circuit capacitor (first short-circuit capacitor), 18 resistance (impedance element), 19 diode (second diode) , 20 short-circuit capacitor (second short-circuit capacitor), 21, 22 charge capacitor (first charge capacitor), 23 charge capacitor (second charge capacitor), 24 charge capacitor (third Capacitor for charging), 25, 26 Output voltage terminal, 31, 32 coils, 33 Charging capacitor Capacitor (first charging capacitor), 41, 42 short-circuit capacitor (third short-circuit capacitor), 43 short-circuit capacitor (fourth short-circuit capacitor), 44 short-circuit capacitor (fifth short-circuit capacitor) , 45 Charging capacitor, 46 Short-circuit capacitor (third short-circuit capacitor), 51 limiter, 52 limiter, 61 SW control circuit, 62 switch.

Claims (12)

  When a modulation signal is input from the connection point, a pair of diodes that rectify the modulation signal, a first diode that is connected to an input side of the pair of diodes via an impedance element, and rectifies the modulation signal; A second diode connected to the output side of the pair of diodes via an impedance element and rectifying the modulation signal; and a second diode connected between a connection point of the output side of the first diode and the pair of diodes. One short-circuit capacitor, a second short-circuit capacitor connected between the input side of the second diode and the connection point of the pair of diodes, and the plurality of diodes connected in parallel with the pair of diodes A first charging capacitor for charging the rectified current generated by the capacitor, and connected between the input side of the pair of diodes and the input side of the first diode. A second charging capacitor for charging a rectified current by the plurality of diodes; and a second charging capacitor connected between an output side of the pair of diodes and an output side of the second diode to charge the rectified current by the plurality of diodes. A power charging circuit comprising three charging capacitors.   2. The power charging circuit according to claim 1, wherein the first and second diodes, the first and second shorting capacitors, and the second and third charging capacitors are stacked in a plurality of stages.   When a modulation signal is input from the connection point, a pair of diodes that rectify the modulation signal, a first diode that is connected to an input side of the pair of diodes via an impedance element, and rectifies the modulation signal; A second diode connected to the output side of the pair of diodes via an impedance element and rectifying the modulation signal; and a second diode connected between a connection point of the output side of the first diode and the pair of diodes. 1 short-circuit capacitor, a second short-circuit capacitor connected between the input side of the second diode and the connection point of the pair of diodes, and a third short-circuit connected in parallel with the pair of diodes Capacitor, a fourth short-circuit capacitor connected between the input side of the pair of diodes and the input side of the first diode, and the pair of diodes. A fifth short-circuit capacitor connected between the output side of the first diode and the output side of the second diode; connected between the input side of the first diode and the output side of the second diode; A power charging circuit comprising a charging capacitor for charging a rectified current by the diode.   4. The power charging circuit according to claim 3, wherein the first and second diodes and the first to fifth short-circuit capacitors are stacked in a plurality of stages.   4. The power charging circuit according to claim 3, wherein the pair of diodes, the first and second diodes, and the first to fifth short-circuit capacitors are integrated into an integrated circuit.   6. A limiter for limiting a rise in the output voltage of the charging capacitor exceeding the reference voltage is connected between the input side of the first diode and the output side of the second diode. The power charging circuit according to claim 1.   6. The power charging circuit according to claim 1, wherein a limiter for limiting an increase in output voltage of the charging capacitor exceeding the reference voltage is connected to a connection point of the pair of diodes. .   8. The power charging circuit according to claim 1, further comprising a switch that disconnects the diode and the charging capacitor when the output voltage of the charging capacitor exceeds a reference voltage. 9.   8. The power charging circuit according to claim 6, further comprising a switch for separating the diode and the charging capacitor when a current flows through the limiter.   The power charging circuit according to any one of claims 1 to 9, wherein the pair of diodes inputs a modulation signal from a feeding point provided in the vicinity of an end of the antenna.   The power charging circuit according to any one of claims 1 to 10, wherein the diode is made of silicon and titanium silicide.   The power charging circuit according to any one of claims 1 to 11, wherein a resistor or a coil having an impedance larger than an input impedance at a connection point of a pair of diodes is used as the impedance element.

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