JPH05135224A - Non-contact communication equipment - Google Patents

Abstract

PURPOSE:To increase an input impedance, to reduce a power consumption, and to reduce cost by generating a wiring voltage in a memory by a boosting means. CONSTITUTION:When a signal is transmitted from a receiver 1 to a receiver 8, a resonance voltage is excited in a resonance circuit constituted of a coil L and a capacitor C1 incorporated by a receiving circuit 2. An input voltage at a point generated by the excitement is inputted to the input side of a constant voltage circuit 3. Then, a constant voltage is generated at the both terminals of a capacitor C2 connected with the output side of the constant voltage circuit 3. The constant voltage at a point Q outputted from the output side of the constant voltage circuit 3 is supplied to both a transmitted signal extracting circuit 4 and a communication circuit 5. Moreover, the input voltage is impressed on the both terminals of the resistance R of a rectifier circuit 9, and rectified by the diode D in the rectifier circuit 9. Then, the diode output voltage at a point Y is inputted to a charge pump 6a, and boosted to a prescribed voltage.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention is efficient in contactless communication used when entry / exit management is performed by a user carrying a card-shaped receiver, and is effective in reducing contactless communication. Concerning the current consumption method.

[0002]

2. Description of the Related Art Conventionally, for example, a user carries out a card-shaped receiver to perform entry / exit management, or a user attaches the receiver to an item and manages receipt / shipment of the item. The receiver 8 having the configuration shown in FIG.

Here, in FIG. 3, the receiving circuit 2 is coupled to the transmitter 1 by electromagnetic coupling or the like. Receiver circuit 2
Is composed of a resonance circuit of a coil L and a capacitor C ₁ and is connected to the input side of the constant voltage circuit 3. A capacitor C ₂ , a transmission signal extraction circuit 4 and a communication circuit 5 are connected in parallel to the output side of the constant voltage circuit 3.
The transmission signal extraction circuit 4 and the communication circuit 5 are connected at a point N. Further, a booster circuit 6 and a memory (EEPROM) 7 are connected in parallel to the output side of the constant voltage circuit 3. The booster circuit 6 includes a charge pump 6a and a 10 MHZ oscillator circuit 6b. A write voltage is input to the memory (EEPROM) 7 from the booster circuit 6. The receiving circuit 2 to the memory (EEPROM) 7 are formed into a chip,
It is built in the card-shaped receiver 8.

Next, the operation will be described. Since the receiving circuit 2 is coupled to the transmitter 1 side by electromagnetic coupling or the like, when a signal is sent from the transmitter 1 side to the receiver 8,
A resonance voltage is excited in the resonance circuit of the coil L and the capacitor C ₁ built in the receiving circuit 2. The input voltage at the point P generated by the excitation is input to the input side of the constant voltage circuit 3. In the constant voltage circuit 3, the input voltage at the point P is detected and rectified, and even if the input voltage at the point P fluctuates to some extent, the output voltage of the constant voltage circuit 3 is not affected as much as possible. Has been done. Therefore, a constant voltage is generated at both terminals of the capacitor C ₂ connected to the output side of the constant voltage circuit 3. The constant voltage (communication input signal) at the point Q output from the output side of the constant voltage circuit 3 is the transmission signal extraction circuit 4
And the communication circuit 5.

Therefore, in the transmission signal extraction circuit 4,
Based on the constant voltage at point Q (communication input signal) output from the output side of the constant voltage circuit 3, a clock signal is generated and output at point N. Then, the clock signal at the point N is supplied to the communication circuit 5 as a timing pulse. The constant voltage (communication input signal) at the point Q output from the output side of the constant voltage circuit 3 is processed by the communication circuit 5. Further, the constant voltage at point Q (communication input signal) output from the output side of the constant voltage circuit 3 is the booster circuit 6 and the memory (EEPR).
OM) 7 is also input. Then, based on the constant voltage at the point Q, a clock signal is generated in the oscillator circuit 6b incorporated in the booster circuit 6. The clock signal is input to the charge pump 6a and a predetermined voltage (20
Boosted to V). The boosted voltage is input to the memory (EEPROM) 7 as the write voltage at the point S. Thereby, the data (communication input signal) is written in the memory (EEPROM) 7. On the other hand, memory (E
The data stored in the EPROM) 7 is processed by the communication circuit 5.

FIGS. 4A to 4C show voltage waveforms at various parts of the circuit shown in FIG. In FIG.
(A) shows the input voltage waveform of the point P input into the input side of the constant voltage circuit 3. As shown in the figure, when the distance from the transmitter 1 side is appropriate, the input voltage waveform at the point P is a signal having a sine waveform of ± 10 to 12V. This signal contains information required by the user. Further, the input voltage at the point P varies depending on the distance from the transmitter 1 side.

FIG. 4B shows a constant voltage waveform output to the output side (point Q) of the constant voltage circuit 3. In the figure, the constant voltage waveform is a waveform in which the signal component e is superimposed on the DC component E of 3 to 5V. As shown in the figure, on the output side (point Q) of the constant voltage circuit 3, the input voltage at the point P is detected and rectified and converted into a constant voltage (DC component E) having a small amplitude of 3 to 5V. Waveform is output. The signal waveform at this point Q also includes information (signal component e) necessary for the user side.

FIG. 4C shows the output side of the booster circuit 6 (point S).
It shows the boost waveform output to. As shown in the figure, on the output side (point S) of the booster circuit 6, the constant voltage at the point Q is boosted, and a boosted waveform of DC 20 V (write voltage).
Is output.

[0009]

In a conventional receiver used for non-contact communication, as shown in FIG. 3, an input voltage (for example, ± 10 to 12 V) from the receiving circuit 2 is stepped down by a constant voltage circuit 3. (For example, 3 to 5 V), and based on the voltage obtained as a result, the booster circuit 6 is used to execute the memory (EE
A write voltage (for example, 20 V) to the PROM) 7 was generated. By the way, since the receiver 8 does not have a built-in power supply, the communicable distance is determined by the memory (EEPROM) 7
It depends (is inversely proportional) to the current consumption of the chip (receiver) including. However, the booster circuit 6 has a built-in oscillator circuit 6b. Moreover, a high frequency (for example, 10 MHZ) is used for the transmission circuit 6b. Therefore, the input impedance on the receiver 8 side becomes low, and the current consumption of the receiver 8 becomes large. At the same time, the communication distance becomes shorter. In addition, the size of the chip (receiver 8) is increased by the amount of the transmission circuit 6b, and the cost is increased.

The present invention has been made in view of such a situation, and does not require a dedicated (high frequency) transmitting circuit 6b for the booster circuit 6 and increases the input impedance on the receiver 8 side. At the same time, the current consumption of the receiver 8 is reduced and the communication distance is increased. Further, it is intended to reduce the size of the chip (receiver 8) and reduce the price.

[0011]

A non-contact communication device according to a first aspect of the present invention comprises a receiving circuit 2 as a receiving means for receiving a signal, and a boosting means for generating a write voltage to a memory (EEPROM) 7. Booster circuit 6 and rectifier circuit 9 as rectifying means connected between the receiving circuit 2 and the booster circuit 6.
And is provided.

In the non-contact communication device according to a second aspect of the present invention, the rectifier circuit 9 has one end connected to the receiver circuit 2 and the other end grounded, and a resistor R for applying a signal from the receiver circuit 2.
And a diode D that has one end connected to the receiving circuit 2 and the resistor R and the other end connected to the booster circuit 6 to rectify the signal applied to the resistor R.

[0013]

In the non-contact communication device according to claim 1,
The signal output from the receiving circuit 2 is input to the boosting circuit 6 via the rectifying circuit 9. Then, in the booster circuit 6, a write voltage to the memory (EEPROM) 7 is generated. As a result, the booster circuit 6 has a dedicated (high frequency)
The transmitter circuit becomes unnecessary and the input impedance becomes high. At the same time, current consumption is reduced and communication distance is increased. Also, the device becomes smaller and the price is reduced.

In the non-contact communication device according to the second aspect, the signal output from the receiving circuit 2 is applied to the resistor R. Then, the signal is rectified by the diode D and input to the booster circuit 6. This simplifies the structure, reduces the size of the device, and reduces the cost.

[0015]

1 is a circuit diagram showing the configuration of an embodiment of a non-contact communication device of the present invention. In the figure, parts corresponding to those in the conventional case of FIG. 3 are denoted by the same reference numerals, and description thereof will be omitted as appropriate. In FIG. 1, a rectifier circuit 9 is connected between the receiver circuit 2 and the booster circuit 6. The rectifier circuit 9 has one end connected to the receiver circuit 2 and the other end grounded to a resistor R, one end connected to the receiver circuit 2 and the resistor R, and the other end connected to the booster circuit 6. It is composed of a diode. The booster circuit 6 has a charge pump 6a but does not have the oscillator circuit 6b.
Other configurations are the same as the conventional case.

Next, the operation will be described. Since the receiving circuit 2 is coupled to the transmitter 1 side by electromagnetic coupling or the like, when a signal is sent from the transmitter 1 side to the receiver 8,
A resonance voltage is excited in the resonance circuit of the coil L and the capacitor C ₁ built in the receiving circuit 2. The input voltage at the point P generated by the excitation is input to the input side of the constant voltage circuit 3. In the constant voltage circuit 3, the input voltage at the point P is detected and rectified, and even if the input voltage at the point P fluctuates to some extent, the output voltage of the constant voltage circuit 3 is not affected as much as possible. Has been done. Therefore, a constant voltage is generated at both terminals of the capacitor C ₂ connected to the output side of the constant voltage circuit 3. The constant voltage (communication input signal) at the point Q output from the output side of the constant voltage circuit 3 is the transmission signal extraction circuit 4
And the communication circuit 5.

Therefore, in the transmission signal extraction circuit 4,
A clock signal is generated based on the constant voltage (communication input signal) at the point Q output from the output side of the constant voltage circuit 3. Then, the clock signal is supplied to the communication circuit 5 as a timing pulse. Further, the constant voltage (communication input signal) at the point Q output from the output side of the constant voltage circuit 3 is the communication circuit 5
Is processed in. Further, the constant voltage (communication input signal) at the point Q output from the output side of the constant voltage circuit 3 is also input to the memory (EEPROM) 7.

On the other hand, the input voltage at the point P is also applied to both ends of the resistor R in the rectifier circuit 9 and the diode D in the rectifier circuit 9 is applied.
Is rectified by. Then, the diode output voltage at the point Y is input to the charge pump 6a and a predetermined voltage (2
It is boosted to 0V). The boosted voltage is input to the memory (EEPROM) 7 as the write voltage at the point S. Thereby, the data (communication input signal) is written in the memory (EEPROM) 7. On the other hand, memory (E
The data stored in the EPROM) 7 is processed by the communication circuit 5.

2 (a) to 2 (d) show voltage waveforms at various parts of the circuit shown in FIG. In FIG.
(A) shows the input voltage waveform of the point P input into the input side of the constant voltage circuit 3. As shown in the figure, when the distance from the transmitter 1 side is appropriate, the input voltage waveform at the point P is a signal having a sine waveform of ± 10 to 12V. This signal contains information required by the user. Further, the input voltage at the point P varies depending on the distance from the transmitter 1 side.

FIG. 2B shows a constant voltage waveform output to the output side (point Q) of the constant voltage circuit 3. In the figure, the constant voltage waveform is a waveform in which the signal component e is superimposed on the DC component E of 3 to 5V. As shown in the figure, on the output side (point Q) of the constant voltage circuit 3, the input voltage at the point P is detected and rectified and converted into a constant voltage (DC component E) having a small amplitude of 3 to 5V. Waveform is output. The signal waveform at this point Q also includes information (signal component e) necessary for the user side.

FIG. 2C shows a diode output voltage waveform output to the output side (point Y) of the diode D. As shown in the figure, the output side of the diode D (point Y)
A diode output voltage waveform (half waveform of a sine wave of 10 to 12 V) obtained by detecting the input voltage waveform at the point P shown in FIG.

FIG. 2D shows the output side of the booster circuit 6 (point S).
It shows the boost waveform output to. As shown in the figure, on the output side (point S) of the booster circuit 6, the diode output voltage at the point Y is boosted, and a boosted waveform (write voltage) of DC 20V is output.

As described above, according to the embodiment of the present invention,
The oscillator circuit 6b becomes unnecessary, and the memory (EEPRO) is directly supplied from the input voltage (voltage at the point P) from the receiver circuit 2.
Since the write voltage for M) 7 is generated, the input impedance on the receiver side becomes high and the current consumption of the receiver becomes small. Along with that, the communication distance increases. Also, the chip (receiver) becomes smaller and the price drops.

In the embodiment of the present invention, if the circuit not involved in the writing of the memory (EEPROM) 7 is not operated or if the constant of the circuit element is selected to be high, the input impedance on the receiver side becomes high. Therefore, the input voltage from the receiving circuit 2 (the voltage at the point P)
Becomes a high voltage, the boosting efficiency is improved.

The non-contact communication mentioned here includes not only electromagnetic coupling but also the case of using light, microwave, electromagnetic wave, ultrasonic wave, or the like.

[0026]

As described above, according to the non-contact communication device of the first aspect, the signal output from the receiving means is input to the boosting means via the rectifying means. Since the voltage for writing to the memory is generated in the booster, the dedicated (high frequency) oscillator circuit for the booster is not required, and the input impedance can be increased.
At the same time, the current consumption can be reduced and the communication distance can be extended. In addition, the chip can be downsized and the price can be reduced.

According to the non-contact communication device of the second aspect, the signal output from the receiving means is applied to the resistor. Then, the signal is rectified by the diode and input to the booster. Therefore, the rectifier circuit can be easily configured, the chip can be made small, and the cost can be reduced.

[Brief description of drawings]

FIG. 1 is a circuit diagram showing a configuration of an embodiment of a non-contact communication device of the present invention.

FIG. 2 is a diagram illustrating voltage waveforms at various parts of the circuit shown in FIG.

FIG. 3 is a circuit diagram showing a configuration of an example of a conventional non-contact communication device.

FIG. 4 is a diagram illustrating voltage waveforms at various parts of the circuit shown in FIG.

[Explanation of symbols]

 1 transmitter 2 receiver circuit 6 booster circuit 7 memory (EEPROM) 8 receiver 9 rectifier circuit R resistance D diode

Claims (2)

[Claims] 1. A non-contact communication device that receives a signal by non-contact communication and writes the received information in a memory, a receiving unit that receives the signal, a boosting unit that generates a write voltage to the memory, A non-contact communication device comprising: a rectifying unit connected between the receiving unit and the boosting unit. 2. The rectifying means has one end connected to the receiving means and the other end grounded, and a resistor to which a signal from the receiving means is applied, and one end connected to the receiving means and the resistor, The non-contact communication device according to claim 1, further comprising a diode having the other end connected to the boosting means and rectifying a signal applied to the resistor.