KR101574058B1 - Data Carrier and Data Carrier System - Google Patents

Abstract

The data carrier 2 is provided with a comparator 41, a capacitor 42, a comparator operation adjusting resistor 43, a resistor voltage dividing circuit 44 and a resistor 45 for reactive current. The capacitor 42 is interposed between the cathode of the PD (photodiode) 21 and the negative input terminal of the comparator 41. The comparator operation regulating resistor 43 is interposed between the plus terminal of the primary cell 271 and the minus input terminal of the comparator 41. [ The resistor voltage divider circuit 44 is constituted by connecting a plurality of voltage dividing resistors 441 and 442 in series. One end of the resistance voltage divider circuit 44 is connected to the positive terminal of the primary battery 271. The connection point between the voltage-dividing resistor 441 and another voltage-dividing resistor 442 is connected to the plus input terminal of the comparator 41. [

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a data carrier and a data carrier system,

The present invention relates to a data carrier system including a data carrier and a reader / writer.

For example, RFID (Radio Frequency Identification) is widely known as a technology for reading and writing data in an IC chip built in a data carrier (RF tag, IC tag, ID tag) by near field wireless communication.

RFID is roughly classified into a propagation type and a magnetic type (electromagnetic induction type) by a data transmission method. In the propagation equation, radio waves carrying data are transmitted and received between the antenna of the reader / writer and the antenna of the data carrier. In the magnetic expression, the coil antenna of the reader / writer and the coil antenna of the data carrier are coupled by electromagnetic induction, and data is transmitted / received between the reader / writer and the data carrier.

The propagation type and magnetic field type have a single end and a single end respectively.

The propagation equation can be manufactured at a relatively low cost and has an advantage of high versatility. Further, since power can be generated by rectification in the data carrier, the data carrier can be configured as a passive tag that does not need a power source (battery). On the other hand, when the communication distance is set to be long, the propagation equation has a drawback that the reader / writer communicates not only with a specific data carrier but also with its surrounding data carrier. In addition, it is susceptible to reflection of radio waves on the metal surface and absorption of radio waves into water, and also has a problem of regulation by the radio wave method and interference with other radio devices.

The magnetic field system is advantageous in that it is difficult to be affected by dust or the like and can be used in a place with bad surrounding environment. In addition, since power can be generated by resonance in the data carrier, the data carrier can be constituted by the passive tag similarly to the propagation type. On the other hand, the magnetic field system has a shortcommunication distance and requires a precision in the positional relationship between the reader / writer and the data carrier for coupling by electromagnetic induction. In addition, there is a drawback that the communication speed is slow because the frequency is low in the magnetic field equation.

Patent Document 1: JP-A-2001-184467

Thus, the inventor of the present invention has devised a data carrier system comprising an optical data carrier and a reader / writer. The optical data carrier system is advantageous in terms of communication distance, directivity and interference compared with the propagation type and magnetic type, and is easily handled in a factory production line or the like. Further, in the optical data carrier system, it is possible to increase the capacity of data transmitted between the data carrier and the reader / writer.

However, in order to transfer data from the data carrier to the reader / writer, a light source such as an LED mounted on the data carrier must emit light, and relatively large power is required for the light emission.

For example, at the time of communication, the reader / writer irradiates the data carrier with strong light to accumulate the power generated in the light receiving element (for example, a photodiode) of the data carrier in the capacitor, A configuration using electric power is conceivable. In this configuration, when the primary cell is not mounted on the data carrier, since the charging of the capacitor is started after the data carrier and the reader / writer enter the communicatable area, it is difficult to store large power in the capacitor in a short time, The data transmission speed from the data carrier to the reader / writer is limited. Therefore, it is preferable to mount a primary cell for supplying operating power to the data carrier.

However, in the data carrier, since the reception circuit needs to be operated so as to be able to receive from the reader / writer during standby other than during communication with the reader / writer, the primary battery is consumed. Further, when DC disturbance light such as sunlight or illumination light enters the light receiving element at the time of standby, an electromotive force is generated in the light receiving element, and the primary cell is consumed by the current due to the electromotive force flowing through the primary battery. For this reason, a large capacity primary battery is required, and the data carrier becomes large.

It is an object of the present invention to provide a data carrier capable of suppressing consumption of power supply power in a standby state and a data carrier system including the data carrier.

In order to achieve the above object, a data carrier according to an aspect of the present invention is a data carrier for carrying out communication using light as a carrier wave with a reader / writer, and includes a light receiving element formed of a diode and a power source And a receiving circuit connected to the light receiving element and the power supply. The receiving circuit includes a comparator, a capacitor interposed between the cathode of the light receiving element and the minus input terminal of the comparator, and a positive A resistor for regulating the operation of the comparator interposed between the terminal and the minus input terminal of the comparator, and a plurality of resistors for partial pressure, one end of which is connected to the positive terminal of the power source, A resistor voltage divider circuit connected to the input terminal; On, it comprises a reactive current for resistance interposed between the cathode and the anode of the light-receiving element.

Light (data modulated by data) containing data is transmitted and received between the data carrier and the reader / writer.

The data carrier is provided with a receiving circuit having a configuration including a comparator, a capacitor, a resistance for adjusting a comparator operation, a resistor voltage divider circuit, and a resistor for a reactive current. The capacitor is interposed between the cathode of the light receiving element and the negative input terminal of the comparator. The resistor for adjusting the operation of the comparator is disposed between the positive terminal of the power source and the negative input terminal of the comparator on the comparator side rather than the capacitor. The resistor voltage divider circuit is constituted by connecting a plurality of voltage dividing resistors in series. One end of the resistance voltage divider circuit is connected to the positive terminal of the power source. The connection point between the resistor for partial pressure and another resistor for partial pressure is connected to the plus input terminal of the comparator. Thus, the potential at the connection point between the voltage dividing resistor and the other voltage dividing resistor (the output voltage of the resistive voltage dividing circuit) is input to the plus input terminal of the comparator as the reference voltage. The resistor for the reactive current is interposed between the cathode and the anode of the light receiving element.

When the light is not incident on the light receiving element, the potential of the minus input terminal of the comparator (the voltage of the power supply) is equal to or higher than the potential of the plus input terminal (the output voltage of the resistive voltage divider circuit) do.

When DC disturbance light such as sunlight or illumination light is incident on the light receiving element and signal light from the reader / writer is not incident, electromotive force due to DC disturbance light is generated in the light receiving element. Since a capacitor is interposed between the cathode of the light receiving element and the negative input terminal of the comparator, even if an electromotive force is generated in the light receiving element, no current flows in the comparator operation regulating resistor and the current (reactive current) Lt; / RTI > Therefore, power of the power source is not consumed.

Therefore, it is possible to suppress the consumption of the power supply power in the standby state in which the signal light from the reader / writer does not enter the light receiving element.

When the signal light (optical pulse) in pulse form is output from the reader / writer and the signal light is incident on the light receiving element of the data carrier, the magnitude of the electromotive force generated in the light receiving element is changed. As the magnitude of the electromotive force changes, a current flows through the resistor for adjusting the operation of the comparator, the capacitor and the light receiving element, and the potential of the negative input terminal of the comparator is changed. Then, during a period in which the potential of the minus input terminal of the comparator falls below the potential of the plus input terminal, a high level signal is outputted from the output terminal of the comparator.

Therefore, during the communication in which the signal light from the reader / writer enters the light receiving element, the received data (data transmitted from the reader / writer) can be obtained from the signal output from the output terminal of the comparator.

A data carrier according to another aspect of the present invention is a data carrier for carrying out communications with a reader / writer using light as a carrier wave, and is connected to one input terminal of a comparator and a comparator, A resistor voltage dividing circuit for reducing the DC voltage of the power supply to a predetermined reference voltage and inputting the reference voltage to the other input terminal of the comparator, And a resistor for reactive current interposed between the cathode and the anode.

Light (data modulated by data) containing data is transmitted and received between the data carrier and the reader / writer.

The data carrier is provided with a comparator, an input circuit, a resistor divider circuit, and a resistor for reactive current. An input circuit is connected to one input terminal of the comparator. The potential of the input circuit, that is, the potential input to one input terminal of the comparator changes in accordance with the magnitude of the magnitude of the electromotive force generated in the light receiving element. The other input terminal of the comparator is supplied with a reference voltage generated by stepping down the DC voltage of the power source to a predetermined reference voltage by the resistor voltage divider circuit. The resistor for the reactive current is interposed between the cathode and the anode of the light receiving element.

When DC disturbance light such as sunlight or illumination light is incident on the light receiving element and signal light from the reader / writer is not incident, electromotive force due to DC disturbance light is generated in the light receiving element. Since the magnitude of the electromotive force hardly changes, the potential input to one input terminal of the comparator hardly changes due to the function of the input circuit. Therefore, even if an electromotive force is generated in the light receiving element, the level of the signal output from the output terminal of the comparator does not change in the state where no light is incident on the light receiving element. At this time, the current due to the electromotive force (reactive current) flows through the resistor for the reactive current. Therefore, the power of the power source is not consumed.

Therefore, it is possible to suppress the consumption of the power supply power in the standby state in which the signal light from the reader / writer does not enter the light receiving element.

When the signal light (optical pulse) in the form of a pulse is output from the reader / writer and the signal is incident on the light receiving element of the data carrier, the magnitude of the electromotive force generated in the light receiving element is changed. The potential of the negative input terminal of the comparator is changed in accordance with the magnitude of the electromotive force. Then, during a period in which the potential of the minus input terminal of the comparator exceeds the potential of the plus input terminal, the level of the signal output from the output terminal of the comparator is inverted.

Therefore, during the communication in which the signal light from the reader / writer enters the light receiving element, the received data (data transmitted from the reader / writer) can be obtained from the signal output from the output terminal of the comparator.

The data carrier may further include a storage section for storing data and a control section for obtaining reception data from a signal output from the reception circuit and generating transmission data using data stored in the storage section based on the reception data .

In this case, the controller preferably comprises an LSI having a CMOS structure operating in a subthreshold region.

By operating the MOSFET in the subthreshold region, the LSI can be operated with very fine power on the order of nA (nanoamperes). The LSI can reduce the operating power of the data carrier by configuring the control unit. In particular, it is possible to suppress the consumption of the power supply power at the time of communication.

The data carrier may further include a driving circuit that uses a direct current voltage of the light emitting element and the power source and supplies a driving current to the light emitting element and the control unit may control a driving current supplied from the driving circuit to the light emitting element based on the transmission data .

In this case, it is preferable that a plurality of light-emitting elements are provided, and a plurality of light-emitting elements are commonly connected to the drive circuit and emit light simultaneously by the drive current supplied from the drive circuit.

A plurality of light emitting elements are synchronously emitted to emit light such as dust to one light emitting element so that transmission data can be transmitted to the reader / writer by light emission from another light emitting element.

The light emitting element is preferably an LED.

Since the LED is a point light source capable of easily controlling the pulse lighting, the LED is used for the light emitting element, so that light whose intensity changes in the pulse shape can be easily output from the light emitting element. Further, since the LED is a diffused light source, it is possible to have a relatively wide directivity for transmission from the data carrier. Therefore, even if the LED does not face the light receiving element of the reader / writer in the direction of the optical axis, the transmission data can be transmitted from the data carrier to the reader / writer.

A data carrier system according to another aspect of the present invention is a data carrier system including a reader / writer and a data carrier for communicating light with a reader / writer as a carrier wave, wherein the data carrier includes a light receiving element composed of a diode And a receiving circuit connected to the light receiving element and the power source. The receiving circuit includes a comparator, a capacitor interposed between the cathode of the light receiving element and the minus input terminal of the comparator, and a capacitor disposed between the capacitor and the capacitor. A comparator for adjusting a comparator operation interposed between a plus terminal of a power source and a minus input terminal of a comparator, and a series circuit of a plurality of voltage dividing resistors, one end of which is connected to a positive terminal of the power source, The resistor connected to the positive input terminal of this comparator And a resistor for reactive current interposed between the cathode of the light receiving element and the anode on the side of the light receiving element rather than the capacitor.

With this configuration, it is possible to obtain the same operational effect as that described with respect to the data carrier.

The reader / writer sets the intensity of the light output from the reader / writer-side light-emitting element, the reader / writer-side light-receiving element and the reader / writer-side light-emitting element to a relatively small intensity and detects the intensity of light received from the data carrier by the reader / The intensity setting section for setting the intensity of the light output from the reader / writer-side light emitting element to a relatively large intensity if the intensity of the light output from the reader / writer-side light emitting element is higher than the first level, A reader / writer side demodulating section (demodulating section) for extracting data stored in the light received by the reader / writer-side light receiving element, provided that the amount of light received from the data carrier by the light receiving element on the reader / writer side is not less than a second level, May be provided.

When the reader / writer-side light-receiving element receives a light quantity of the first level or higher from the data carrier in response to the light of relatively low intensity from the light-emitting element on the reader / writer side, it is judged that the data carrier enters the communicable area of the reader / writer . Then, in a state in which the data carrier enters the communicatable area of the reader / writer, light of a relatively large intensity is output from the light emitting element at the reader / writer side. When the light receiving element on the reader / writer side receives the light amount of the second level or higher which is set lower than the first level from the data carrier, the demodulator on the side of the reader / writer is controlled so as to pick up the data on the light, have. Therefore, stable communication can be performed between the data carrier and the reader / writer.

According to the present invention, it is possible to suppress the consumption of the power supply power in the standby state in the data carrier. On the other hand, when the signal light from the reader / writer is incident on the light receiving element of the data carrier, the received data contained in the signal light can be obtained.

1 is a block diagram showing a configuration of a data carrier system according to an embodiment of the present invention.
2 is a block diagram showing an electrical configuration of a data carrier and a reader / writer.
3 is a circuit diagram showing a configuration of a data carrier receiving circuit.
4 is a diagram for explaining the relationship between the manner of outputting the light from the reader / writer (the manner of outputting the signal from the output terminal of the comparator) and the data (sign).
5 is a block diagram showing an example of the configuration of a data carrier mounted on a device fixedly disposed in a factory or the like.
Fig. 6 is a block diagram showing an example of the configuration of a data carrier mounted on a press device used for a crimping operation of a wire harness terminal. Fig.
7 is a block diagram showing the configuration of a data carrier including a plurality of light emitting devices (LEDs).

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a block diagram showing a configuration of a data carrier system 1 according to an embodiment of the present invention.

The data carrier system 1 includes a data carrier 2 for holding data and a reader / writer 3 for reading and writing data to and from the data carrier 2. Light is used as a carrier wave for communication between the data carrier 2 and the reader / writer 3. [ That is, the data carrier system 1 is an optical data carrier system that performs communication using light as a carrier wave between the data carrier 2 and the reader / writer 3.

The data carrier system 1 is used, for example, in the management of products flowing in a production line of a factory. In this case, the data carrier 2 is mounted on each product flowing in the production line of the factory, and the reader / writer 3 is fixedly arranged with respect to each production line. When the data carrier 2 enters the communicatable area of the reader / writer 3 according to the flow of each product, the communication between the data carrier 2 and the reader / The information about the product held in the reader / writer 3 is collected. The reader / writer 3 is connected to the host PC4 at regular or arbitrary timing, and the information collected in the reader / writer 3 is transferred from the reader / writer 3 to the host PC4. Thus, in the host PC4, products flowing through a plurality of production lines can be unifiedly managed.

Fig. 2 is a block diagram showing the electrical configuration of the data carrier 2 and the reader / writer 3. Fig.

The data carrier 2 includes a PD (photodiode) 21, an LED 22, a control unit 23, a memory 24, a modulating unit 25, a demodulating unit 26 and a power supply unit 27 .

The control unit 23 includes a CPU and is configured by an LSI having a CMOS structure that operates in a subthreshold region. The control unit 23 executes a program stored in the memory 24 and controls the operation of each unit such as writing / reading data to / from the memory 24. [

The memory 24 is, for example, a flash memory.

The modulating section 25 includes a driving circuit (driver) 251 for supplying a driving current to the LED 22. When the data (transmission data) from the data carrier 2 to the reader / writer 3 is transmitted, the control unit 23 controls the drive circuit 251 based on the data, and the LED 22 is pulsed. Thus, the data is transmitted on the pulse light output from the LED 22.

The demodulation section 26 includes a reception circuit 261. [ The receiving circuit 261 will be described later.

The power supply unit 27 includes a primary battery 271. The power supply section 27 supplies the power of the primary battery 271 to the control section 23, the memory 24, the modulation section 25 and the demodulation section 26. The primary battery 271 is, for example, a manganese dioxide lithium battery. Concretely, from the viewpoint of battery capacity and size, the primary battery 271 employs, for example, a coin-shaped lithium battery "CR2025 ".

The reader / writer 3 includes an LD (laser diode) 31, a PD (photodiode) 32, a control unit 33, a memory 34, a modulating unit 35, a demodulating unit 36, And an external interface 38. Fig.

The LD 31 is, for example, a red laser diode.

The control unit 33 includes a CPU and executes a program stored in the memory 24. The control unit 33 controls operations of each unit such as writing / reading of data to / from the memory 34. [

The memory 34 is composed of, for example, a dynamic random access memory (DRAM).

The modulating section 35 includes a driving circuit (driver) 351 for supplying a driving current to the LED 22. The drive circuit 351 is controlled by the control unit 33 based on the data when the data is transmitted from the reader / writer 3 to the data carrier 2, and the LD 31 is pulsed. Thus, the data is transmitted on the light outputted from the LD 31.

The demodulation section 36 includes a reception circuit 361. [ When a signal light output from the data carrier 2 is incident on the PD 32, an electromotive force due to the photovoltaic effect is generated in the PD 32. The electromotive force of the PD 32 is changed in accordance with the intensity of the signal light. In the receiving circuit 361, a signal for switching between the high level and the low level is generated in accordance with the change of the electromotive force of the PD 32. [ This signal is outputted from the receiving circuit 361 to the control section 33. [ In the control unit 33, a signal output from the receiving circuit 361 is converted into data, and the data is acquired as received data from the data carrier 2. [

The power supply section 37 supplies power to the control section 33, the memory 34, the modulation section 35 and the demodulation section 36. [ The power supply unit 37 may include, for example, a built-in battery as a power supply or a circuit for generating operating power of each unit from an external power supply (for example, commercial AC power supply, USB bus power, etc.).

The external interface 38 is an interface for communication with the host PC4 (see Fig. 1). For example, a USB (Universal Serial Bus) interface is adopted as the external interface 38. [

3 is a circuit diagram showing the configuration of the receiving circuit 261 (demodulating section 26) of the data carrier 2. In Fig. 4 is a diagram for explaining the relationship between the output mode of the light from the reader / writer 3 (the output mode of the signal from the output terminal of the comparator) and the data (sign).

The receiving circuit 261 includes a comparator 41, a capacitor 42, a comparator operation adjusting resistor 43, a resistor voltage dividing circuit 44 and a resistor 45 for reactive current.

The comparator 41 has a plus input terminal 411, a minus input terminal 412, and an output terminal 413.

The capacitor 42 is interposed between the cathode of the PD 21 and the negative input terminal 412 of the comparator 41. Specifically, one electrode of the capacitor 42 is connected to the cathode of the PD 21 via the wiring 46. [ The other electrode of the capacitor 42 is connected to the negative input terminal 412 of the comparator 41 through the wiring 47. [

One end of the comparator operation regulating resistor 43 is connected to the positive terminal of the primary battery 271 of the power source section 37. [ The other end of the resistor 43 for adjusting the operation of the comparator is connected to the wiring 47. That is, the comparator operation regulating resistor 43 is interposed between the plus terminal of the primary battery 271 and the minus input terminal 412 of the comparator 41. [

The output terminal 413 of the comparator 41 is connected to the control section 23.

The resistor voltage divider circuit 44 is constituted by connecting two resistors 441 and 442 for dividing voltage in series. One end of the resistance voltage divider circuit 44 is connected to the positive terminal of the primary battery 271. The connection point 443 of the resistors 441 and 442 for partial voltage is connected to the positive input terminal 411 of the comparator 41. The other end of the resistance voltage divider circuit 44 and the anode of the PD 21 are connected to the ground GND.

The resistor voltage divider circuit 44 may be constituted by connecting three or more voltage dividing resistors in series.

The resistor 45 for the reactive current is interposed between the cathode of the PD 21 and the anode. Specifically, one end of the resistor 45 for the reactive current is connected to the wiring 46. The other end of the resistor 45 for the reactive current is connected to the ground.

An electromotive force due to the DC disturbance light is not generated in the PD 21 in the state where no light is incident on the PD 21 and no current flows through the wiring 46 connected to the cathode of the PD 21, The current does not flow to the wiring 47 connected to the capacitor 46 via the capacitor 42. Therefore, the potential of the wiring 47 is the same potential as that of the positive terminal of the primary battery 271 of the power supply section 37. On the other hand, a current flows through the resistor voltage divider circuit 44. A resistor having a relatively large resistance value is used for the resistor 442 on the minus side of the resistor voltage divider circuit 44. The current flowing through the resistor voltage divider circuit 44 is, for example, about 100 nA. The positive input terminal 411 of the comparator 41 is supplied with a voltage obtained by subtracting the voltage drop of the primary side battery 271 from the positive side voltage divider resistor 441. Therefore, the potential of the negative input terminal 412 of the comparator 41 is higher than that of the positive input terminal 411, and a low level signal is output from the output terminal of the comparator 41.

(DC power) due to the DC disturbance light is generated in the PD 21 in a state in which the DC disturbance light such as sunlight or illumination light enters the PD 21 and the signal light from the reader / writer 3 is not incident do. At this time, although a current flows in the wiring 46 connected to the cathode of the PD 21, the capacitor 42 is interposed between the cathode of the PD 21 and the negative input terminal 412 of the comparator 41 Therefore, even if an electromotive force due to DC disturbance light is generated in the PD 21, no current flows through the wiring 47. [ The potential of the negative input terminal 412 of the comparator 41 is higher than the potential of the positive input terminal 411 and the low level signal is outputted from the output terminal of the comparator 41. [ The current (reactive current) flowing through the wiring 46 flows through the resistor 45 for the reactive current.

As described above, in the standby state in which the signal light from the reader / writer 3 is not incident on the PD 21 and communication is not performed between the data carrier 2 and the reader / writer 3, It does not flow. Therefore, the power consumption of the primary battery 271 of the power supply unit 37 is consumed by the minute current flowing through the resistance voltage dividing circuit 44. [ Therefore, in the configuration of the receiving circuit 261, it is possible to suppress the consumption of the power (power supply power) of the primary battery 271 in the standby state in which the signal light from the reader / writer does not enter the PD 21. [ As a result, the life of the primary battery 271 can be prolonged.

In the standby state, that is, before the data carrier 2 mounted on the product flowing in the production line enters the communicable area with the reader / writer 3, the intensity of light output from the LD 31 in the reader / It is set to small intensity. The control unit 33 controls the driving circuit 351 of the modulating unit 35 so that the communication start instruction for instructing the start of the communication is transmitted by the light having a small intensity output from the LD 31, do.

The communication start command is data represented by an array (bit string) of "1" and "0". The data "1" and "0" are transmitted by the shortest time interval from the lighting of the LD 31 to the next lighting, with one lighting time Ton of the LD 31 fixed as shown in FIG. 4 . For example, after a lapse of a relatively short time T1 from the lighting of the LED 31, the LED 31 is turned on again to transmit data "1 ". On the other hand, the LED 31 is turned on again after a lapse of a relatively long time TO from the lighting of the LED 31, so that data "0" is transmitted.

When the data carrier 2 enters the communicable area with the reader / writer 3, the light (signal light) containing the communication start command is incident on the PD 21 of the data carrier 2. When the signal light from the reader / writer 3 is incident on the PD 21 of the data carrier 2, the magnitude of the electromotive force generated in the PD 21 is changed. A current flows through the comparator operation regulating resistor 43, the capacitor 42 and the PD 21 in accordance with the magnitude of the electromotive force and the potential of the minus input terminal 412 of the comparator 41 is changed. A high level signal is output from the output terminal 413 of the comparator 41 during a period in which the potential of the negative input terminal 412 of the comparator 41 is lower than the potential of the positive input terminal 411.

In the control unit 23, the data (sign) is decoded from the signal output from the output terminal 413 of the comparator 41.

That is, when the high-level signal is outputted from the output terminal 413 of the comparator 41 in the state where the communication between the data carrier 2 and the reader / writer 3 is not started, Then, the signal output from the output terminal 413 of the comparator 41 is decoded into data until the low level signal continues to be outputted over a predetermined time longer than the time T0. When the time from when the high level signal is outputted from the output terminal 413 of the comparator 41 to when the next high level signal is outputted is a relatively short time T1, the control section 23 sets the data "1" . On the other hand, when the time from when the high level signal is output from the output terminal 413 of the comparator 41 to when the next high level signal is outputted is a relatively long time T0, the control section 23 sets the data "0" .

Then, the control unit 23 determines whether or not the acquired series of bit strings corresponds to the communication start command.

If it is determined that the bit string corresponds to the communication start command, it is determined that the control section 23 has received the communication start command from the reader / writer 3. In this case, the control unit 23 controls the drive circuit 251 of the modulating unit 25 so that the LED 22 is pulsed, and the communication approval data indicating that the communication is approved is output from the LED 22 And transmitted by light.

When the light containing the communication approval data is incident on the PD 32 of the reader / writer 3, the reader / writer 3 in the reader / writer 3 receives the signal from the signal output from the receiving circuit 361 of the demodulating unit 36, Approval data is acquired.

For example, the receiving circuit 361 is provided with two comparators having different sensitivities (reference voltages) in parallel. When the light receiving the communication approval data is received, the communication approval data (for example, a comparator to which a relatively low reference voltage is input in a configuration in which the reference voltage is input to the plus input terminal) Communication is not started between the data carrier 2 and the reader / writer 3 even if the communication acknowledgment data is acquired from the signal output by the comparator with a relatively high sensitivity. Communication between the data carrier 2 and the reader / writer 3 is started when the communication acknowledgment data is acquired from a signal output by the comparator with a relatively low sensitivity.

When the communication between the data carrier 2 and the reader / writer 3 is started, in order for the reader / writer 3 to perform stable communication with the data carrier 2, the intensity of light output from the LD 31 is relatively It is changed to a large intensity.

Thereafter, the control unit 33 controls the drive circuit 351 of the modulating unit 35 so that a transmission request command for requesting transmission of the predetermined data to the data carrier 2 is sent to the light output from the LD 31 And transmitted.

When the light containing the transmission request command is incident on the PD 21 of the data carrier 2, the control section 23 outputs the same to the PD 21 of the data carrier 2 from the output terminal 413 of the comparator 41 The signal is decoded into data. The transmission request command is acquired by this decoding. The control unit 23 reads predetermined data from the memory 24 in response to the acquisition of the transmission request command. The drive circuit 251 of the modulator 25 is controlled by the control unit 23 so that the LED 22 is turned on and the predetermined data read from the memory 24 is output from the LED 22 And transmitted by light.

When the light containing the predetermined data is incident on the PD 32 of the reader / writer 3, the reader / writer 3 causes the control section 33 to extract predetermined data . Then, the control unit 33 records the predetermined data in the memory 34. [

After the communication between the data carrier 2 and the reader / writer 3 is started, for example, data is acquired from a signal output by a comparator with a relatively high sensitivity. Thus, even if the light from the data carrier 2 is weak, the reader / writer 3 can obtain the data stored in the light from the data carrier 2 well.

Thereafter, the control unit 33 controls the drive circuit 351 of the modulating unit 35 to terminate the communication with the data carrier 2 by the light output from the LD 31 .

A signal output from the output terminal 413 of the comparator 41 is decoded into data by the control unit 23 and the communication end command is transmitted to the PD 21 of the data carrier 2 . In response to the acquisition of the communication end command, the communication between the data carrier 2 and the reader / writer 3 is terminated.

On the other hand, after the communication between the data carrier 2 and the reader / writer 3 is started, the intensity of light output from the LD 31 is switched to a relatively large intensity at a relatively small intensity. The intensity of the light may be constant before and after the start of the communication between the data carrier 2 and the reader / writer 3. [

Although two comparators having different sensitivities are provided in parallel in the receiving circuit 361 of the demodulating unit 36 of the reader / writer 3, the number of comparators provided in the receiving circuit 361 may be one.

A comparator with a higher sensitivity than the comparator 41 is provided in parallel with the comparator 41 in the receiving circuit 261 of the data carrier 2 demodulating section 26 and the comparator 41 is provided between the data carrier 2 and the reader / After the commencement of the communication, data may be acquired from the current outputted by the high-sensitivity comparator. Thus, even if the signal light incident on the PD 21 of the data carrier 2 (light output from the reader / writer 3) is weak, the data carrier 2 can acquire data in the signal light well .

In the data carrier 2, the control unit 23 is constituted by an LSI having a CMOS structure in which it operates in the sub-sector-ward area. Thereby, the operating power of the control section 23 can be reduced, and the power consumption of the primary battery 271 by the operation of the control section 23 can be suppressed. As a result, the service life of the primary battery 271 can be further extended.

The LED 22 is a point light source capable of easily controlling pulse lighting. In the data carrier 2, since the LED 22 is used as the light emitting element, it is possible to easily output light whose intensity changes in the form of a pulse. Further, since the LED 22 is a diffused light source, it is possible to have a relatively wide directivity for transmission from the data carrier 2. Therefore, the transmission data can be transmitted from the data carrier 2 to the reader / writer 3 even when the LED 22 does not face the PD 32 of the reader / writer 3 in the optical axis direction.

Although the embodiment of the present invention has been described above, the present invention may be embodied in other forms.

For example, although the above-described embodiment deals with the case where the data carrier 2 is mounted on a moving body such as a product flowing in a production line, the data carrier 2 is mounted on a device fixedly disposed in a factory, May be used to store and maintain the state of the < / RTI >

5 is a block diagram showing an example of the configuration of the data carrier 2 mounted on a device fixedly disposed in a factory or the like.

As shown in Fig. 5, a detector 51 for detecting the state of the device is mounted on the device to which the data carrier 2 is mounted. The detector 51 is provided with an LED 52 and the data carrier 2 is provided with a phototransistor 61 constituting the LED 52 and a photo-coupler. When the state of the device is detected by the detector 51, an electric signal indicating the state of the device is converted into light between the LED 52 and the phototransistor 61, and the light is returned to the electric signal again , The state of the device is transmitted from the detector 51 to the data carrier 2. When the data carrier 2 receives the state of the apparatus, the state of the received apparatus is recorded in the memory 24 by the control unit 23.

The state of the apparatus includes, for example, the temperature of the apparatus, the temperature and / or humidity of the environment in which the apparatus is used, the number of operations of the apparatus (for example, the number of presses in the press apparatus), the good and / And the like.

When the state of the device is stored and held in the data carrier 2, for example, when the defect occurs in the device or the defect rate increases, the reader / writer 3 reads the state of the device from the data carrier 2 , The read information can be helpful in the analysis of the cause of the defect and the countermeasure of the defect. As a result, the quality of the product can be improved.

Further, when the data carrier 2 is mounted on a device fixedly disposed in a factory or the like, a configuration for detecting the state of the device in the data carrier 2 may be provided.

In the case where the data carrier 2 is mounted on a press device used for the crimping operation of a wire harness terminal, the data carrier 2 is provided with, for example, a piezoelectric transducer A detection circuit 72 for detecting the natural vibration when the applicator moves up and down from the output signal of the piezoelectric transducer 71 and a detection circuit 72 for detecting the number of times of detection of the natural vibration by the detection circuit 72 And a coefficient circuit 73 for counting. The number of times counted by the counting circuit 73 is input to the control section 23 and the number of times thereof is recorded in the memory 24 by the control section 23.

According to this configuration, the number of times (the number of times of use) stored and held in the memory 24 from the data carrier 2 is read by the reader / writer 3, so that the life of the consumable used in the press apparatus Can be well managed.

The data carrier 2 may be provided with a plurality of light emitting devices. For example, as shown in FIG. 7, the data carrier 2 may be provided with two LEDs 221 and 222. FIG. In this case, the two LEDs 221 and 222 are turned on in synchronization with each other, so that the transmission data is stored in the light output from each of the LEDs 221 and 222. Thus, even if a foreign object such as dust is attached to one LED 221, transmission data can be transmitted to the reader / writer 3 by light emission from the other LED 222. [

Data may be transmitted to the data carrier 2 by the reader / writer 3 and the data may be recorded in the memory 24 of the data carrier 2. [ For example, when a device on which the data carrier 2 is mounted is provided with a member requiring calibration, the time at which the calibration is to be performed, Or may be recorded in the memory 24. When a device on which the data carrier 2 is to be mounted is provided with a member requiring replacement, when the exchange is performed, the date and time at which the exchange is to be performed, 24). Thus, when the reader / writer 3 reads the information such as the state of the device from the data carrier 2, information about the calibration timing or the exchange timing is read together to acquire a period until the calibration period or the exchange period can do.

Although the embodiments of the present invention have been described in detail, it is to be understood that the present invention is not limited to the specific examples thereof, And ranges are limited only by the appended claims.

For example, it is assumed that an LD (laser diode) 31 composed of a red laser diode is provided as a light emitting element of the reader / writer 3. The present invention is not limited to this, and the light emitting element of the reader / writer 3 may be a laser diode that outputs laser light of a color other than red. The light emitting element of the reader / writer 3 is not limited to a laser diode but may be an LED. The LED may be a red LED or an infrared LED.

For example, when the reader / writer 3 is a long-range handy type which is operated at a relatively far position from the data carrier 2, it is preferable that a red laser is employed as the light emitting element of the reader / writer 3. It is possible to recognize that the laser light output from the reader / writer 3 is irradiated onto the data carrier 2 by employing the red laser. A red LED or an infrared LED may be employed as the light emitting element of the reader / writer 3 when the reader / writer 3 is a short-handed type operated at a relatively close position from the data carrier 2 or a fixed type arranged fixedly. For example, a red LED is employed for the reader / writer 3 of the short-distance handy type, and an infrared LED may be employed for the reader / writer 3 of the fixed type.

In addition, it is possible to carry out various design changes within the scope of the matters described in the claims of the present invention.

1: data carrier system 2: data carrier
3: Reader / writer 21: PD (light receiving element)
22: LED (light emitting element) 23:
24: Memory (storage unit) 25: Modulation unit
26: demodulation unit 27: power supply unit
41: comparator 42: capacitor (input circuit)
43: Comparator operation adjusting resistor 44: Resistance voltage dividing circuit
45: Resistance for reactive current 46: Wiring (input circuit)
221: LED (light emitting element) 222: LED (light emitting element)
251: driving circuit 261: receiving circuit
271: Primary cell 411: Positive input terminal
412: Negative input terminal 441: Resistance for partial pressure
442: Resistance for partial pressure 443: Connection point

Claims (7)

A data carrier for communicating with a reader / writer using light as a carrier wave,
A light receiving element composed of a diode,
A power source for generating a DC voltage,
And a receiving circuit connected to the light receiving element and the power source,
The receiving circuit includes:
A comparator,
A capacitor interposed between a cathode of the light receiving element and a minus input terminal of the comparator;
A comparator operation adjusting resistor interposed between a plus terminal of the power source and a minus input terminal of the comparator, on the comparator side,
A resistive voltage divider circuit comprising a series circuit of a plurality of voltage dividing resistors, one end of which is connected to a positive terminal of the power source, and a connection point between the two voltage dividing resistors is connected to a plus input terminal of the comparator,
And a resistor for reactive current interposed between the cathode of the light receiving element and the anode on the light receiving element side than the capacitor,
Wherein when the current does not flow through the resistor for adjusting the operation of the comparator, the potential of the minus input terminal of the comparator is higher than the potential of the plus input terminal of the comparator and a low level signal is outputted from the output terminal of the comparator, Wherein a potential input to the positive input terminal of the comparator is higher than a potential of the negative input terminal of the comparator and a high level signal is output from the output terminal of the comparator. delete The method according to claim 1,
A storage unit for storing data;
And a control unit for acquiring reception data from the signal output from the reception circuit and generating transmission data using data stored in the storage unit based on the reception data. The method of claim 3,
Wherein the control unit comprises an LSI having a CMOS structure operating in a subthreshold region. 5. The method of claim 4,
A light-
Further comprising a driving circuit which uses a DC voltage of the power source and supplies a driving current to the light emitting element,
Wherein the control unit controls the driving current supplied from the driving circuit to the light emitting element based on the transmission data. 6. The method of claim 5,
A plurality of the light emitting elements are provided,
Wherein the plurality of light emitting elements are commonly connected to the drive circuit and emit light simultaneously by a drive current supplied from the drive circuit. A data carrier system comprising a reader / writer and a data carrier communicating with the reader / writer using light as a carrier,
The data carrier includes:
A light receiving element composed of a diode,
A power source for generating a DC voltage,
And a receiving circuit connected to the light receiving element and the power source,
The receiving circuit includes:
A comparator,
A capacitor interposed between a cathode of the light receiving element and a minus input terminal of the comparator;
A comparator operation adjusting resistor interposed between a plus terminal of the power source and a minus input terminal of the comparator, on the comparator side,
A resistor voltage divider circuit including a series circuit of a plurality of voltage dividing resistors, one end of which is connected to the plus terminal of the power source, and the connection point between the two dividing resistors is connected to the plus input terminal of the comparator,
And a resistor for reactive current interposed between the cathode of the light receiving element and the anode on the light receiving element side than the capacitor,
Wherein when the current does not flow through the resistor for adjusting the operation of the comparator, the potential of the minus input terminal of the comparator is higher than the potential of the plus input terminal of the comparator and a low level signal is outputted from the output terminal of the comparator, The potential input to the positive input terminal of the comparator is higher than the potential of the negative input terminal of the comparator and the high level signal is output from the output terminal of the comparator.

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