JP2561020B2 - Non-contact data setting device and communication system using the same - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a non-contact type data setting device that is electromagnetically coupled and a communication system using the same.

[0002]

2. Description of the Related Art Conventionally, there is a communication system having a fixed machine (master station) and a transponder (slave station) that are electromagnetically inductively coupled to each other to transmit and receive signals. The transponder has a separate I
By setting the D code, the fixed machine can identify each slave station.

As a method of setting the ID code of each transponder, a method using a jumper wire, a setting pin, a pattern cut, or an EPROM is known.

[0004]

However, in any of these conventional examples, it is necessary to incorporate setting work into the process of assembling the printed circuit board of the transponder. This setting work has a drawback that the setting work itself requires a lot of work such as setting various ID codes, and the manufacturing efficiency of the transponder is lowered. In addition, in manufacturing the transponder, the ID code setting and the transponder obtained thereby must be associated with each other, and after manufacturing,
Those having the same set ID code must be stored separately from other ones, which makes it difficult to manage as a product and lacks mass productivity. Furthermore, after completing the transponder as a product, it may be possible to carry out the code setting work according to the order from the user side, but in the case of a transponder that is entirely covered with a case to protect it from oil and dust, When the case is opened at the time of setting and the case is closed after the setting, there is a defect that a sealing failure occurs and the durability is unexpectedly reduced.

In this way, conventionally, the ID code of the transponder is simply set appropriately on the transponder side, and the fixed machine and the transponder are electromagnetically inductively coupled to each other so that the fixed machine can transfer any ID to the transponder.
There is no such thing as sending a D-code for storage in a transponder.

According to the present invention, not only the writing information such as an ID code is transmitted to and stored in the non-contact type response device which is a communication partner, but the contents of the writing information transmitted to the non-contact type response device can be confirmed. The task is to do so.

[0007]

A first non-contact type data setting device of the present invention is a non-contact type data setting device for transmitting an electromagnetic wave for power supply in which writing information is superimposed on a communication partner. an antenna coil for electromagnetic induction coupling with respect to the partner station, and setting means for setting the write information to be transmitted, it superimposes the write information set by the setting means to the electromagnetic wave for power supply the antenna and transmitting means for transmitting from the coil, after the signal sent from the setting means, said demodulating means takes out the write result from the feedback signal from the communication partner received by the antenna coil, the write result and the setting unit taken out by the demodulating means in and a check means for the transmission by comparing the corresponding write information previously configured to check whether proper performed.

A second non-contact data setting device of the present invention is a non-contact data setting device for transmitting an electromagnetic wave for power supply, which is superposed with writing data and address information for designating the writing position, to a communication partner. an apparatus, wherein an antenna coil for electromagnetic induction coupling with respect to exchange <br/> Shin partner, and setting means for setting the address information for the write data and the write position designation to be transmitted, by the setting means before this the set address information for data and its writing position for the specified write superposed on the electromagnetic wave for power supply
And transmitting means for transmitting the serial antenna coil, after the signal sent from the setting means, and demodulating means for retrieving the write data and address information of the write location for the specified from the feedback signal from the communication partner received by the antenna coil, wherein a and to transmit the proper collation corresponding write data and address information of the write location for the specified set previously by the write data and address information and the setting means of the write position for the specified extracted in demodulating means It is provided with a confirmation means for confirming whether or not it has been performed.

A first communication system of the present invention is a communication system having a non-contact type data setting device and a non-contact type responding device which are electromagnetically inductively coupled to each other to transmit and receive signals.
The non-contact data setting device transmits an electromagnetic wave for power supply on which write information is superimposed from the first antenna coil , and the non-contact response device is transmitted from the non-contact data setting device. the electromagnetic wave for power supply superimposed write information is received by the second antenna coil, in addition to storing the write information as well as operation to obtain the operating power based on the received signal, said the stored write information
The non-contact type data setting device feedback-transmits from the second antenna coil to the non-contact type data setting device side, and the non-contact type data setting device also uses the first antenna coil to write information sent back from the non-contact type responding device. By receiving and collating this with the corresponding writing information previously transmitted to the non-contact type response device, it is confirmed whether or not the transmission was properly performed.

A second communication system of the present invention is a communication system having a non-contact type data setting device and a non-contact type responding device which are electromagnetically inductively coupled to each other to transmit and receive signals.
The non-contact type data setting device transmits an electromagnetic wave for power supply in which write data and address information for designating the write position are superimposed from the first antenna coil , and the non-contact type response device is a non-contact type response device. Second, the electromagnetic wave for power supply on which the write data transmitted from the formula data setting device and the address information for designating the write position are superimposed .
The antenna coil receives and operates the operating power based on the received signal to operate, and stores the write data at the position specified by the address information. The stored write data and the address information are stored in the second antenna. Ko
From the contactless data setting device to the non-contact type data setting device side, and the non-contact type data setting device also uses the first antenna coil to write data and its address information which are sent back from the non-contact type response device. By receiving and collating this with the corresponding write data and the address information for specifying the write position previously sent to the non-contact type response device, it is possible to confirm whether or not the transmission was properly performed. is there.

[0011]

The non-contact type data setting device of the present invention not only gives the operating power and the writing information to the non-contact type responding device side, but also sends the writing information returned from the non-contact type responding device in advance. By comparing with the information, it is possible to confirm whether or not the transmission was properly performed.

Further, not only the write data but also the address information for designating the write position of the write data is transmitted to the non-contact type response device to specify the write position to the non-contact type response device to obtain the required write data. It is supposed to be written.

The communication system of the present invention is a combination of the above-mentioned non-contact type data setting device and a non-contact type response device which is a communication partner of the non-contact type data setting device. The electric power is received from the non-contact type data setting device, the writing information received from the non-contact type data setting device is stored in the storage means as the operating power, and the writing information received from the non-contact type data setting device is also stored. Information is returned to the non-contact type data setting device side.

In the communication system, the write information may be write data and address information for designating the write position thereof.

[0015]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described in detail below based on the embodiments shown in FIGS. In this embodiment, an example in which the non-contact type data setting device is the fixed machine A and an example in which the non-contact type response device is the transponder B are given,
Also, an example is given in which the write information is a code signal when the ID code is set from the fixed device A to the transponder B. The stationary machine A and the transponder B constitute a communication system.

FIG. 1 is a circuit block diagram of a fixing machine according to an embodiment of the present invention. The fixing machine A is provided at a predetermined position in the middle of a tool movement path of an automatic production line in an unmanned factory or the like, at a side of the side. It is fixedly installed. In the figure, 1 is a first antenna coil, and the first antenna coil 1 has
A power supply unit 2 and a reception unit 3 that perform code setting and power supply
And are connected via a coupling circuit 4.

The power supply unit 2 has an oscillator circuit (OSC) 5 for generating a high frequency signal, a code setting unit 6 for setting a specific code signal having an address section and a data section, and a code signal for modulation. A modulation circuit 7 and an amplification circuit 8 for amplifying a high frequency signal on which a code signal is superimposed are provided.
The code setting circuit 6 corresponds to the setting means in the claims, and the modulation circuit 7 and the amplifier circuit 8 correspond to the transmitting means in the claims.

The receiver 3 includes an amplifier circuit 9 and a demodulator circuit 1.
0, a serial-parallel conversion circuit (SPC) 11, and a matching circuit 12 as the confirmation means of the claims. The amplifier circuit 9 and the demodulation circuit 10 described above correspond to the demodulation means in the claims. The collating circuit 12 receives the code signal from the code setting unit 6, compares the code signal with the code signal that has been feedback-transmitted from the transponder B side, which will be described later, and determines whether the code signal is set correctly. You can check.

FIG. 2 is a circuit block diagram of a transponder according to an embodiment of the present invention. The transponder B is equipped with a tool (not shown). In the figure, 13 is a second antenna coil that is coupled to the first antenna coil 1 by electromagnetic induction.
Includes a power receiving unit 14 and a receiving unit 15 for setting a code signal.
And the transmission unit 16 are connected via a switching circuit 17. The power receiving unit 14 and the transmitting unit 16 include a switch circuit 18
Connected through. The switching circuit 17 and the switching circuit 18 are switching-controlled by the timing control circuit 19. The timing control circuit 19 sends an I signal to the EPROM 20.
Controls data writing such as D code. EPR
The OM 20 may be a non-volatile storage device such as a PROM.

The power receiver 14 is provided with a rectifier circuit 21 for converting the AC output from the second antenna coil 13 into DC, and a capacitor 22 for storing the DC charge. The receiving unit 15 includes an amplification circuit 23 and a demodulation circuit 24. The transmitter 16 includes a modulation circuit 25 and an amplification circuit 26.

Stationary machine A and transponder B described above
Although not shown, each is covered with a case made of a material such as brass or copper to protect it from oil and dust. The first antenna coil 1 and the second antenna coil
The antenna coil 13 is magnetically coupled by approaching the antenna coil 13 by, for example, about 5 mm.

FIG. 3 is a circuit diagram showing in detail the periphery of the switching circuit 17, the rectifying circuit 21, and the switching circuit 18 in the transponder B. In this figure, 27 is the second.
A resonance capacitor for resonating with the antenna coil 13. In this configuration, the switching circuit 17 and the switching circuit 18 are controlled by the timing control circuit 19, the switching circuit 17 is switched, and the rectifying circuit 21 and the receiving unit 15 are switched.
Are connected to the second antenna coil 13, and the switch circuit 18 is opened.
The charge is accumulated in. At this time, the accumulated charge is basically the rectifier circuit 2 unless the switch circuit 18 is closed.
No leakage current except the leakage current from 1 and self-discharge.
On the other hand, by switching the switching circuit 17, the transmission unit 16 is connected to the second antenna coil 13 and the switching circuit 18 is closed so that a predetermined code signal can be transmitted by using the electric charge accumulated in the capacitor 22 as an operating power source. It has become.

Next, the operation of this embodiment will be described with reference to the time chart of FIG. The high frequency signal generated by the oscillator circuit 5 of the stationary device A is set by the code setting unit 6 by b
A specific code signal having an address part and a data part as shown in FIG. 3 is superimposed and modulated to obtain a signal as shown in a, and the high frequency signal a is provided to the first antenna at set time intervals by the control means (not shown). The coil is supplied to the coil 1 to excite the first antenna coil 1. The first antenna coil 1 generates a magnetic field according to the high frequency signal a as described above,
This magnetic field electromagnetically couples the second antenna coil 13 of the transponder B, and the electromagnetic induction causes the second antenna coil 13 to generate an AC output as shown in c.
This AC output c is converted into DC by the rectifier circuit 21 via the switching circuit 17, and a rectified output as shown in d is output.

The rectified output d is supplied to the capacitor 22, and the DC charge is stored in the capacitor 22. Further, the AC output c from the second antenna coil 13 is supplied to the amplifier circuit 2
In addition to the amplification by 3, the demodulation circuit 24 demodulates the original code signal as shown by e. When the amount of charge stored in the capacitor 22 exceeds a predetermined threshold level L, the timing control circuit 19 causes the EPROM as shown in f
A read / write signal (R / W signal) is output to 20 and predetermined data is written to a predetermined address of the EPROM 20 based on the code signal. The timing control circuit 19 controls the switching circuit 17 after a predetermined time elapses.
A timer output to each of the switch circuit 18 to switch the switching circuit 17 to connect the transmitter 16 to the second antenna coil 13, and switch the switch circuit 18 to supply the charge stored in the capacitor 22 to the transmitter 16. Then, using this as an operating power source, as shown in h, the EP
The code signal written in the ROM 20 is read and input to the modulation circuit 25, and the modulated signal g is amplified by the amplification circuit 2
The signal is amplified by 6 and supplied to the second antenna coil 13 to excite the second antenna coil 13.

In the second antenna coil 13, a magnetic field corresponding to the above-mentioned modulation signal g is generated, the first antenna coil 1 is electromagnetically coupled by this magnetic field, and the electromagnetic induction induces a magnetic field from the first antenna coil 1 to the modulation signal g. Generates a signal corresponding to. This signal is amplified by the amplification circuit 9, demodulated by the demodulation circuit 10, and then converted into a parallel signal by the serial-parallel conversion circuit 11, and then, in the collation circuit 12, the code setting unit 6
It is checked whether or not a predetermined code signal is written in the EPROM 20 by comparing with the code signal set in the above. The transmission of the code signal from the transponder B to the fixed device A is set to be performed in a time zone corresponding to the non-transmission of the high frequency signal from the fixed device A to the transponder B. By the way, if the signal transmission from the fixed machine A to the transponder B is performed unilaterally as in the present invention, in the case where the magnetic coupling between the first and second antenna coils 1 and 13 is weak, the transponder B is used. Although it is feared that wrong code setting may be performed due to occurrence of bit loss in the received code signal, even if such a situation should occur, the present invention can grasp the situation by the confirmation operation, Appropriate code can be set, for example, it becomes possible to take measures such as retransmitting a signal.

A tool is provided for each of the transponders B in which the specific code signal is written in this way, and the transponder B with the tool is placed on a predetermined transport path and provided separately (or. By reading the code signal of the transponder B sequentially conveyed by the code signal reading device (also used for the stationary machine A), it is possible to determine what kind of tool the transponder B is equipped with, and the determination Based on the result, a predetermined tool is selected and held by the holder to perform a predetermined processing operation.

The present invention is not limited to the above embodiment. For example, each of the first and second antenna coils 1 and 13 is not limited to the ferrite coil as shown in the figure, but a loop coil may be used. Further, it is also possible to prepare a large number of the transponders B and arrange them in a fixed manner, and move the stationary machine A side with respect to them. Further, in the above-described embodiment, the write data and the address information for designating the write are the code signals when the ID code is set from the fixed device A to the transponder B. It goes without saying that it can be applied as address information for designating a writing position. In addition, the non-contact type data setting device can be an IC card data reading device in addition to the stationary device A, and the non-contact type responding device can be an IC card in addition to the transponder B.

[0028]

According to the first non-contact type data setting device of the present invention, the writing information is transmitted at the same time as the power supply to the communication partner, and it is confirmed whether or not the information can be written to the communication partner without fail. Thus, highly reliable transmission can be performed. As a result, the non-contact type response device, which is a communication partner, can have a structure that does not have an operating power source, and can simplify the structure of the communication partner and reduce the cost.

In the second non-contact type data setting device of the present invention, not only the write data but also the address information for designating the write position is transmitted to the communication partner, and the contactless data communication partner becomes the contact partner. Since it is possible to omit the configuration for addressing as the answering machine, it is possible to simplify the configuration of the communication partner and reduce the cost. In particular, in the first and second non-contact type data setting devices of the present invention, the antenna coil for transmitting the electromagnetic waves for supplying information and power and the antenna coil for receiving the feedback signal are used in common, so that Miniaturization is possible.

Further, in the communication system of the present invention, the signal received by the non-contact type response device is non-contact for some reason such as when the connection between the non-contact type data setting device and the non-contact type response device is weak. Even if the signal is different from the signal sent from the data setting device, this error can be grasped by the confirmation operation on the non-contact data setting device side. As a result, it is possible to perform highly reliable signal transmission.

When the ID information for the non-contact type response device is used as the writing information transmitted from the non-contact type data setting device of the present invention, the ID code of the non-contact type response device is arbitrarily set according to the user's request. Therefore, it is not necessary to provide a configuration for setting an ID code for each non-contact type response device as in the related art, and it is possible to save the labor of setting the ID code in the manufacturing process of the non-contact type response device. Therefore, for the manufacture of non-contact type response devices, it is sufficient to manufacture products of the same standard evenly.
In addition to contributing to the improvement of production efficiency, the manufacturing line and product storage management can be simplified, which will contribute to a significant cost reduction. Moreover, unlike the conventional case, it is not necessary to open the case of the non-contact type response device when setting the code, so that the sealing property and the durability are not deteriorated as in the conventional case, which contributes to the improvement of the product reliability. Like In particular, in the communication system of the present invention, in the non-contact type data setting device, the antenna coil for transmitting the electromagnetic waves for information and power supply and the antenna coil for receiving the feedback signal are both used, so that the device can be downsized. Further, even in the non-contact type response device, since the antenna coil for receiving the electromagnetic wave for supplying information and power and the antenna coil for transmitting the feedback signal are used in common, the device can be downsized.

[Brief description of drawings]

FIG. 1 is a circuit block diagram of a stationary machine according to an embodiment of the present invention.

FIG. 2 is a circuit block diagram of a transponder according to an embodiment of the present invention.

FIG. 3 is a circuit diagram of a main part of the transponder shown in FIG.

FIG. 4 is a time chart for explaining the operation of the fixed machine and the transponder.

[Explanation of symbols]

 A fixed machine (non-contact type data setting device) 1 first antenna coil 3 of fixed machine 3 reception section 5 oscillation circuit 6 code setting section 7 modulation circuit 8, 9 amplification circuit 10 demodulation circuit 12 matching circuit B transponder (non-contact type response device) apparatus)

Claims (4)

(57) [Claims] 1. A non-contact data setting apparatus for transmitting an electromagnetic wave for power supply superimposed writing information to the partner station, an antenna coil for electromagnetic induction coupling with respect to the partner station, to be transmitted setting means for setting the write information, a transmitting means for transmitting this by superimposing write information set by the setting means to the electromagnetic wave for power supply from the antenna coil, after the signal transmitted from the setting unit, wherein and demodulating means for extracting a write result from the feedback signal from the communication partner received by the antenna coil, the proper said transmission by comparing the write information corresponding set earlier in the writing result and the setting unit taken out by the demodulating means A non-contact type data setting device, comprising: a confirmation means for confirming whether or not it has been performed. 2. A non-contact data setting apparatus for transmitting an electromagnetic wave for power supply by superimposing the write data and address information of the write location for specified for the partner station, the electromagnetic to the partner station power and antenna coil, and setting means for setting the address information for specifying the write data and the write position to be transmitted, the write data set by the setting means and the address information of the write location for the specified inductive coupling and transmitting means for this is superimposed on the electromagnetic wave for supplying transmitted from the antenna coil, wherein after the signal transmitted from the setting unit, the write data and its designated write position from the feedback signal from the partner station received by the antenna coil demodulation means for retrieving the address information of use, write data and its write extracted by the demodulating means And confirmation means for transmitting by collating the write data and address information of the write location for the specified confirms whether properly performed corresponding previously set at the position specified for the address information and the setting means, A non-contact data setting device, characterized by being provided. 3. A communication system comprising a non-contact type data setting device and a non-contact type responding device, which are electromagnetically inductively coupled to each other to transmit and receive a signal, wherein the non-contact type data setting device superimposes write information. An electromagnetic wave for power supply is transmitted from the first antenna coil , and the non-contact type response device includes an electromagnetic wave for power supply on which the write information transmitted from the non-contact type data setting device is superimposed on the second antenna. The coil receives the write information based on the received signal to operate, and the write information is stored. The stored write information is stored in the second antenna.
The non-contact type data setting device feedback-transmits to the non-contact type data setting device side, and the non-contact type data setting device also sends write information returned from the non-contact type responding device to the first antenna coil.
It is to check whether or not the transmission was properly performed by receiving the information by the user and collating it with the corresponding writing information previously transmitted to the non-contact type response device. Communications system. 4. A communication system comprising a non-contact type data setting device and a non-contact type responding device which are electromagnetically inductively coupled to each other to transmit and receive a signal, wherein the non-contact type data setting device includes write data and its writing. An electromagnetic wave for power supply on which address information for position specification is superimposed is transmitted from the first antenna coil , and the non-contact type response device includes write data transmitted from the non-contact type data setting device and a write position thereof. The electromagnetic wave for power supply on which the address information for designation is superimposed is supplied to the second antenna.
The tenor coil receives the operating power based on the received signal to operate, and the write data is stored in a position specified by the address information. The stored write data and the address information are stored in the second antenna coil.
From the non-contact type data setting device to the non-contact type data setting device side, and the non-contact type data setting device receives the write data and the address information sent back from the non-contact type responding device by the first antenna coil. Then, by collating this with the corresponding write data and the address information for designating the write position transmitted to the non-contact type response device, it is confirmed whether or not the transmission is properly performed. A communication system characterized by the above.