JP2006295943A - Read-write processing device for rfid tag - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To adjust a distance between an antenna part and an RFID tag so as to perform communication in a stable state even if a noise level is varied. <P>SOLUTION: A reader/writer 1 and an RFID tag 2 exchange commands and responses via antenna coils 11, 23. In a test mode prior to measurement, a control section 10 of the reader/writer 1 carries out processes of communications with the RFID tag iteratively a plurality of times and each time the communication is made successful, the number of times of that success is counted. When the processes of communications are completed predetermined times, the control section 10 determines a communication success rate and displays it on a display section 15. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to an apparatus (read / write processing apparatus) that performs non-contact communication with an RFID tag incorporating a semiconductor memory to read information from or write information to the semiconductor memory.

  In recent years, a storage system in which various kinds of information are written is attached to goods to be transported, and a system that reads information in a non-contact manner by wireless communication with the storage medium has been introduced in the baggage management site and factory assembly lines. ing. This system is called an RFID system (Radio Frequency Identification System). The storage medium attached to the article contains an IC chip including a semiconductor memory, an antenna coil for communication, and the like, and is called an RFID tag or a non-contact IC tag. Hereinafter, it is referred to as “RFID tag” or simply “tag”.

  A conventional read / write processing device for an RFID system is configured as a reader / writer in which an antenna unit and a control unit are incorporated in the same casing, or a controller separated from the antenna unit. A conventional read / write processing device transmits a command in a predetermined format to an RFID tag and receives a response to the command from the RFID tag in both cases of reading and writing information. When an RFID tag having no internal power supply is used, an induced electromotive force is generated in the antenna coil on the RFID tag side by a transmission wave from the antenna unit to drive a control circuit in the RFID tag. ing.

  Since the RFID system as described above is generally introduced in an environment in which various devices are installed, various noises may be mixed in the communication area between the tag and the antenna unit, resulting in a communication error. For this reason, prior to the system operation, it is necessary to adjust the distance between the tag and the antenna unit so that trial communication is performed and communication with the RFID tag is not hindered.

  In view of this point, the applicant has previously set a test mode in the read / write processing device, and in this test mode, performed read / write processing while adjusting the distance from the tag, and in the event that a communication error has occurred, Has been proposed (see Patent Document 1).

Japanese Patent No. 2610897

  In the invention disclosed in the above-mentioned Patent Document 1, since it is only checked whether or not a communication error has occurred, even if the communication is successful, it is determined how much margin the communication is executed with. Absent. However, in an environment where an RFID system is installed, there is a possibility that noise may fluctuate greatly, for example, sudden noise may occur or noise may increase due to the introduction of new equipment. Therefore, if the tag is installed near the boundary of the communication area of the antenna section or the noise level is higher than the general level, such as when the communication margin is small, the noise level will be a little. A communication error may occur just by going up.

  Further, in the conventional RFID system, the communication process with the same content is repeated a plurality of times in order to cope with the fluctuation of noise. However, even with such control, if the state of noisy continues, all communication may fail. Therefore, when setting the distance between the RFID tag and the antenna unit, it is desirable to secure a margin enough to perform communication even if a certain level of noise occurs.

  In the conventional RFID system, communication is generally performed after the tag is stopped in front of the antenna unit. However, in recent factory assembly lines, there are cases in which communication processing is performed while moving the tag without stopping it due to the fact that it is required to shorten the tact of the production line in order to reduce costs. is increasing.

  When communication is performed while moving the RFID tag, it is necessary to complete the communication while the tag is within the communication area of the antenna unit. For this reason, it is desirable to adjust the time required for the tag to pass through the communication area to be sufficiently longer than the time required for the communication with the tag. Also, when communicating while moving the tag, it is desirable to be able to communicate multiple times in preparation for noise.

  The time required for one communication becomes longer as the transmission / reception data capacity increases. When communication is performed while moving a tag, there is a restriction that communication must be completed while the tag is in the communication area. Therefore, the larger the data capacity, the smaller the number of communications that can be performed.

  As described above, when communication is performed while the tag is moved, the number of times that communication can be performed is limited. Therefore, the necessity of performing communication while ensuring a sufficient margin for noise is further increased.

The present invention has been made paying attention to the above problem, and when adjusting conditions related to communication between the antenna unit and the RFID tag prior to actual measurement, even if the noise level fluctuates, communication can be performed in a stable state. The purpose is to make adjustments that can be made.
The main condition related to communication is the distance between the antenna unit and the tag. When communication is performed while moving the tag, the moving speed of the tag, the data capacity of transmission / reception, and the like are further added to the above conditions.

  In this specification, “communication margin” refers to how much noise the communication possible state can handle in the state in which communication with the RFID tag is possible. Can think. It can be considered that the greater the margin of communication, the more resistant to fluctuations in noise, and the more stable communication processing with the RFID tag can be performed. Further, the communication margin varies depending on the distance between the RFID tag and the antenna unit. When communication is performed while moving the tag, the communication margin varies depending on the moving speed of the tag and the data capacity of transmission / reception.

  The read / write processing apparatus according to the present invention is for communicating with an RFID tag including a semiconductor memory to read / write information from / to the semiconductor memory, and preferably includes a computer control unit. This read / write processing device can be configured as a reader / writer including an antenna unit (including an antenna coil and a circuit for signal transmission / reception) for communication with an RFID tag. However, the configuration of the read / write processing device is not limited to this, and may be configured as a controller separated from the antenna unit. Alternatively, it may be configured as a controller of a type including a transmission circuit and a reception circuit in the antenna unit.

  A first read / write processing device according to the present invention includes a communication processing unit that executes a communication process with the RFID tag, and an information generation unit that generates information indicating a margin of communication based on a communication performance of the communication processing unit. And notification means for displaying or outputting information indicating the margin of communication created by the information creating means to the outside. The communication processing means, information creation means, and notification means described above are also introduced in second to seventh read / write processing devices.

  In the above, the communication processing means and the information creating means can be set by incorporating a processing program for each means into the computer constituting the control unit. The communication processing means is preferably configured to transmit either a read command or a write command to the RFID tag via the antenna unit and recognize the content of the response received by the antenna unit. The communication process may include at least one command transmission and reception of a response to the command. Further, this communication processing can include transmission of a command for identifying the type of RFID tag, memory configuration, etc. (system read) and reception of a response to the command (hereinafter, transmission of this system lead). And receiving the response is called “preliminary communication”).

  The information creating means determines whether or not a correct response to the command transmission is obtained for each hourly communication process while the communication processing means performs a plurality of times of the communication process, and from the history of the determination result Information indicating a margin of communication can be created. The information indicating the communication margin includes the number of successful (or failed) communication, the communication success rate or failure rate, a numerical value converted into frequency and%, information indicating the level of margin (1, 2, 3..., One of a plurality of levels such as A, B, and C). When communication is performed while moving the tag, the data capacity that can be transmitted while the tag passes through the communication area and the number of possible communication with the tag can be used as information indicating a margin. Note that, in a plurality of communication processes to be discriminated by the information creating means, it is desirable to always transmit a command having the same content, but this is not restrictive, and the content of the command may be changed at a predetermined time.

  In the case where the notifying means is configured as means for displaying information indicating the margin of communication, the notifying means can display numerical values and characters themselves, and can also indicate numerical values by replacing them with analog displays such as graphs. In addition, when displaying information indicating a level, an indicator lamp is provided for each level to turn on the corresponding indicator lamp, or one indicator lamp is turned on by switching the display color according to the level to be displayed. be able to. Such a display means can be provided on the surface of the housing constituting the apparatus main body of the read / write processing apparatus.

  Further, when the notification means is configured as means for outputting the information indicating the communication margin to the outside, this means should be an interface for output to a host device such as a personal computer or a programmable logic controller (PLC). Can do. Further, this output is not limited to a digital signal, and can be output as an analog signal.

  According to the above read / write processing device, since the information indicating the margin of communication during a plurality of communication processes is displayed or displayed in the form of display or output, the user can determine how much the margin of communication is You can guess if there is.

  In the second read / write processing device according to the present invention, the information creating means counts the number of times the communication processing means has succeeded or failed during execution of a plurality of times of communication processing, and uses the counted value as the count value. Based on this, the margin of communication is obtained.

  In the counting process, it is desirable to determine whether or not a correct response to the command transmission is obtained in each communication process, and count the number of successes or failures according to the determination result. In this case, when the communication processing for the predetermined number of times is completed, the ratio or difference with respect to the predetermined number of communication processing can be obtained for the count value up to that time. As a result, a numerical value indicating the degree of communication success or the degree of failure can be obtained as the communication margin.

  According to the second read / write processing device, the degree of success in communication during the execution of a plurality of communication processes or the degree of failure in the communication is notified in the form of display or output. It can be estimated how much the communication margin is. For example, when the communication success rate is notified, it can be considered that the higher the notified value is, the larger the margin is. Conversely, when the communication failure rate is notified, it can be considered that the margin is larger as the notified numerical value is lower.

  The third read / write processing device according to the present invention includes a transmission level adjusting means for adjusting a level of a transmission signal to the RFID tag, the transmission level adjusting means, in addition to the communication processing means, the information creating means, and the notifying means. Control means for controlling the operation of the communication processing means while adjusting the transmission level by using a determination means for determining whether communication with the RFID tag can be appropriately executed based on the processing result of the communication processing means, These means are included. The control means causes the communication means to start communication with the RFID tag in a state where the level of the transmission signal is set to a certain value, and then the determination means performs communication while repeatedly executing the communication process. The transmission signal level is changed to a value lower than the current value when it is determined that the transmission signal can be appropriately executed. Further, in this case, the information creation means may determine whether the communication margin based on the level of the transmission signal at the time when the determination means determines that the communication cannot be properly performed or the number of times the level of the transmission signal has been changed up to that time. Create information indicating the degree.

  In the above, it is desirable that the transmission level adjusting means is incorporated in the antenna unit as a circuit for changing the Q value of the antenna coil. For example, a transmission level adjusting means is constituted by a plurality of resistors and a switching circuit for turning on / off the connection of these resistors, and the level of the transmission signal is changed by switching the magnitude of the resistance with respect to the antenna unit. be able to.

  The control means and the discrimination means can be set by incorporating a necessary program in a computer constituting the control unit. Note that the control means may perform control so that the above-described communication processing is executed at least once under the condition that the level of the transmission signal is set to a certain value, but as with the second read / write processing device. A plurality of communication processes may be executed. The control means may instruct the communication processing means to terminate the communication process when the determination means determines that the communication cannot be properly executed.

  Assuming that the distance between the RFID tag and the antenna unit is constant, the power that can be supplied to the RFID tag decreases as the level of the transmission signal decreases. As a result, it can be considered that the level of the response signal from the RFID tag becomes small, and the possibility that the communication process will fail increases. Therefore, when communication processing is executed while the transmission level is gradually reduced with the transmission signal level used in normal read / write processing (hereinafter referred to as “normal transmission level”) as an initial value, the communication processing fails. It can be considered that the greater the difference between the transmission level at the time of the transmission and the normal transmission level, the greater the margin of communication.

  Based on the above idea, the control means can execute the communication process while gradually reducing the level of the transmission signal from a predetermined initial value. In the process of changing the level of the transmission signal, the level may be decreased by a certain ratio or by a certain value. However, the present invention is not limited to this, and there is some variation in the fluctuation range of each level. Also good. This also applies to the following fourth read / write processing device.

  The determining means can determine that the communication can be appropriately executed when a correct response is obtained with respect to the command.

  The information creation means determines at least whether the communication margin at the time when it is determined that the communication cannot be performed properly corresponds to a pass level or a fail level, and the determined level is determined as the communication margin. Can be used as information. When determining the level, the transmission level when it is determined that communication cannot be properly executed is compared with a predetermined threshold value. If the transmission level falls below the threshold value, the transmission level is acceptable. If the level exceeds the threshold value, it can be determined that the level is a failure level.

  Further, in the third read / write processing device, when counting the number of times of changing the level of the transmission signal, a method of comparing the count value at the time of communication failure with a predetermined threshold can be used. In this case, when the count value exceeds the threshold value, it is determined that the level is acceptable.

  In addition, when counting the number of times the level of the transmission signal is changed, a numerical value obtained by multiplying the count value by a predetermined number can be set as information indicating the margin of communication. For example, if the transmission signal level change can be executed a maximum of 5 times, if 10 points are set for each change, the margin of communication can be shown with a maximum of 50 points.

  When the information indicating the margin of communication is expressed as a pass level or a fail level, the notification means displays information indicating the margin of communication using a plurality of indicator lights, multicolor light emitting type indicator lights, or the like. Can do. When information indicating the margin of communication is output, for example, a determination result by a digital signal can be output with a pass level of “1” and a reject level of “0”. Note that the output in this case is also preferably performed on a host device such as a personal computer or a PLC, as in the first read / write processing device.

  When the information indicating the margin of communication is expressed as a score, a display capable of displaying the score (such as a 7-segment LED display or a liquid crystal panel) can be used as the notification means. Also in this case, a digital signal or an analog signal indicating the number of points can be output to the host device.

  Next, in the fourth read / write processing device according to the present invention, in addition to the communication processing means, the information creating means, the notifying means, a transmission level adjusting means for adjusting a level of a transmission signal to the RFID tag, and Control means for controlling the operation of the communication processing means while adjusting the level of the transmission signal using the transmission level adjusting means is included. The control means in the fourth read / write device causes the communication processing means to execute two or more predetermined number of cycles of communication processing and sets the level of the transmission signal from the current value every time one cycle of communication processing is completed. Also change to a lower value. In addition, when the communication processing for the predetermined number of cycles is completed, the information creating means is based on whether the communication is properly executed up to the predetermined number of cycles, or the communication is appropriately executed. Based on the minimum value of the transmitted signal level, information indicating the degree of margin of communication is created.

  In the above, the transmission level adjusting means can be the same as that in the third read / write processing device. The control means can also be set by incorporating a necessary program in a computer constituting the control unit, like the control means of the third read / write processing device, although the contents of the control are slightly different.

  In the third read / write processing device, when communication is properly executed, the next transmission level is reduced, and the margin of communication is determined when communication cannot be properly executed. On the other hand, in the fourth read / write processing device, regardless of the communication result, the transmission level can be reduced every time the communication process for one cycle is completed while executing the communication process for a predetermined cycle. it can. In the communication process for one cycle, the communication process with the RFID tag may be executed at least once. However, as described later, a plurality of communication processes may be performed.

  The information creating means determines the margin of communication in the same manner as the third read / write processing device, depending on how long the communication has been properly performed or the minimum value of the transmission level when the communication has been properly performed. It is possible to determine and set information indicating the determination result (pass level / fail level etc.) as information indicating a margin of communication. Alternatively, a ratio or difference between the number of cycles in which communication is appropriately performed with respect to the total number of cycles in the communication processing may be obtained, and this may be used as information indicating a margin of communication. Alternatively, a numerical value obtained by multiplying the number of cycles in which communication is appropriately performed by a predetermined number of points may be used as information indicating the margin of communication (for example, when performing communication processing of 5 cycles, 10 points per cycle) ), The communication margin can be shown with a maximum of 50 points.) Furthermore, the minimum value of the transmission level when communication is performed properly, the number of cycles where transmission is not performed properly, and the like may be used as information indicating the margin of communication.

  In the third and fourth read / write processing devices, the control means controls the adjustment operation of the transmission level adjusting means so that the transmission signal becomes the maximum level at the time of the first communication processing by the communication processing means. Is desirable. If this maximum level is used as the above-described normal level, it is possible to ensure a sufficient margin for communication during full-scale read / write processing.

Next, a fifth read / write processing device according to the present invention comprises a reception gain adjusting means for adjusting an amplification factor of a signal received from an RFID tag, in addition to the communication processing means, information creating means, and notification means, Control means for controlling the operation of the communication processing means while adjusting the amplification factor of the received signal from the RFID tag using the reception gain adjusting means, and appropriate communication with the RFID tag based on the processing result of the communication processing means Each means of discrimination means for discriminating whether or not it can be executed is included.
The control means starts the communication processing means with the RFID tag in a state where the amplification factor is set to a certain value, and then repeatedly executes the communication processing while the determination means performs communication. The amplification factor of the received signal is changed to a value lower than the current value in accordance with the determination that it can be properly executed. The information creating means includes information indicating a margin of the communication based on the amplification factor of the received signal at the time when the determination device determines that the communication cannot be properly performed or the number of times the amplification factor has been changed so far. create.

  The fifth read / write processing device changes the amplification factor of the received signal instead of the process of adjusting the level of the transmission signal in the third read / write processing device. The reception gain adjustment means is incorporated in the antenna unit as means for switching the resistance value of the feedback resistor of the operational amplifier of the reception circuit, for example. The control means and the discrimination means can be set by incorporating a necessary program in the control unit, as in the third read / write processing device. The information creation means can also have the same configuration as the information creation means of the third and fourth read / write processing devices.

  When the distance between the RFID tag and the antenna unit is constant and the level of the transmission signal is also constant, the smaller the amplification factor of the reception signal, the lower the possibility that the signal from the RFID tag can be demodulated. It can be considered that there is a high possibility of failure. Therefore, when communication processing is executed when the amplification factor set in normal read / write processing (hereinafter referred to as “normal amplification factor”) is set as the initial value and communication processing is executed while decreasing the amplification factor step by step, It can be considered that the greater the difference between the amplification factor at 1 and the normal amplification factor, the greater the margin of communication.

  In the fifth read / write processing device, the communication process can be repeatedly executed while the gain of the received signal is decreased stepwise from a predetermined initial value. In this case as well, in the process of changing the amplification factor, the value may be changed by a constant ratio or by a constant value, but this is not a limitation, and there is some variation in the fluctuation range of the amplification factor each time. May be. This also applies to the following sixth read / write processing device.

  The discriminating means can discriminate whether or not the communication can be appropriately executed depending on whether or not a correct response is obtained with respect to the command. As in the third read / write processing device, the information creating means discriminates the margin of communication by dividing it into at least two levels of a pass level and a fail level, and the information indicating the determined margin indicates the margin of communication It can be. In this case, the amplification factor when it is determined that communication cannot be properly executed is compared with a predetermined threshold value. If the amplification factor is below the threshold value, the level is acceptable and the amplification factor is the threshold value. If it exceeds the value, it can be determined that the level is unacceptable.

  Furthermore, the fifth read / write processing device also counts the number of times the gain of the received signal is changed, and compares the count value at the time of communication failure with a predetermined threshold value to determine the communication margin. Either the pass level or the fail level can be information indicating the margin of communication. It is also possible to multiply the count value of the number of times of changing the amplification factor by a predetermined number of points, and set the obtained numerical value as information indicating the margin of communication.

  Next, in a sixth read / write processing device according to the present invention, in addition to the communication processing means, the information creating means, and the notifying means, a reception gain adjusting means for adjusting an amplification factor of a signal received from an RFID tag, and Control means is included for controlling the operation of the communication processing means while adjusting the gain of the received signal using the reception gain adjusting means. The control means causes the communication processing means to execute two or more predetermined number of cycles of communication processing, and changes the amplification factor to a value lower than the current value every time one cycle of communication processing is completed. In addition, when the communication processing for the predetermined number of cycles is completed, the information creating means is based on whether the communication is properly executed up to the predetermined number of cycles, or the communication is appropriately executed. Information indicating the margin of communication is created based on the minimum value of the amplification factor of the transmission signal at that time.

  In the sixth read / write processing device, the reception gain adjusting means and the communication processing means are the same as those in the fifth read / write processing device. The discriminating means, the control means, and the capability information creating means are the same as those in the fourth read / write processing device except that the processing for adjusting the level of the transmission signal is changed to processing for changing the amplification factor of the reception signal. It can be operated. Therefore, in the sixth read / write processing device, it is possible to create information indicating the margin of communication and to notify the information depending on to which stage of the communication processing of a plurality of cycles has been properly performed. it can.

  In the fifth and sixth read / write processing devices, the adjustment operation of the reception gain adjusting means can be controlled so that the amplification factor becomes the maximum value during the initial communication processing by the communication processing means. If this maximum amplification factor is used as a normal amplification factor, it is possible to ensure a sufficient margin for communication during full-scale read / write processing.

In the present invention, the following modes can be set as modes common to the third and fifth read / write processing devices.
In this aspect, each time the determination unit executes two or more predetermined number of communication processes, the determination unit counts the number of successful or failed communication in the predetermined number of communication processes, and based on the count value, It is determined whether or not communication can be properly executed.

  According to the above aspect, the communication processing is repeated a plurality of times while maintaining the transmission signal level in the third read / write processing device and the reception signal amplification factor in the fifth read / write processing device, respectively. It is possible to determine whether or not the communication can be appropriately executed based on the number of successes or failures in the plurality of communication processes. If the determination result is that communication can be performed properly, the control means may change the level or amplification factor of the transmission signal, and further execute communication processing a plurality of times under the changed conditions. it can. In this aspect as well, as in the second read / write processing device, it is desirable to transmit a command having the same contents in a plurality of communication processes. However, the present invention is not limited to this. May be changed.

In the present invention, the following modes can be set as modes common to the fourth and sixth read / write processing devices.
In this aspect, the one-cycle communication process executed by the communication processing means includes a plurality of communication processes with the RFID tag. In the communication processing of each cycle, the information creation unit appropriately executes the communication of each cycle based on the counting unit that counts the number of times of success or failure of the communication in each cycle and the count value obtained by the counting unit. Discriminating means for discriminating whether or not it has been performed, and creating information indicating the margin of communication using the discrimination result of the discriminating means for each cycle.

  In the above aspect, for example, the determination unit calculates a ratio of the count value to the total number of communication processes within one cycle or a difference between the total number and the count value, and sets the difference value to a predetermined value. By comparing with the threshold value, it is possible to determine whether or not the communication in each cycle has been appropriately executed.

  According to the aspect common to the third and fifth read / write processing apparatuses and the aspect common to the fourth and sixth read / write processing apparatuses, a normal response can be received from the RFID tag by a plurality of communication processes. Even if it is possible, if the degree of communication failure is large, it can be determined that the communication cannot be performed properly. In this way, it is considered that the communication cannot be properly executed when the accuracy of the communication process falls below a certain level. Therefore, adjustment processing (such as adjustment of the positional relationship between the RFID tag and the antenna unit) for stably performing communication can be executed with higher accuracy.

  Next, in the seventh read / write processing device according to the present invention, the communication processing executed by the communication processing means includes preliminary communication processing with the RFID tag. The seventh read / write processing device is provided with control means for controlling the operation of the communication processing means in addition to the communication processing means, the information creating means, and the notification means. The control means causes the communication processing means to repeatedly execute the preliminary communication processing, shift to the main communication processing in response to the success of the preliminary communication processing, and repeatedly execute the main communication processing for a predetermined cycle. In addition, the operation of the communication processing means is controlled.

In the above, in preliminary communication processing executed by the communication processing means, processing for transmitting a command (system read) for identifying the RFID tag type, memory configuration, etc., and receiving a response from the tag to the command Processing can be executed. In the seventh read / write processing device, this preliminary communication process is repeatedly executed, and when the communication process is successful, a substantial command is transmitted to the tag, and the main communication process for receiving a response to the command is repeated for a predetermined cycle. be able to.
For the preliminary communication process, the maximum number of repetitions may be determined in advance, and if the communication is not successful even when the maximum number of times is reached, the communication process may be interrupted.

  The seventh read / write processing device is particularly useful for a case where communication is performed while moving the RFID tag. Even if the preliminary communication process is executed, if the RFID tag is not in the communication area of the antenna unit, a response from the tag to the command cannot be obtained, so the communication fails. When the RFID tag enters the communication area and becomes ready to respond to the command in the preliminary communication, the preliminary communication process is successful, so the communication process can be started.

  The information creating means can create information indicating a margin of communication based on the communication performance of the communication process. Various types of processing described for the first and second read / write processing devices can be applied to the creation of this information. Further, if the configuration added in the second to sixth read / write processing devices is incorporated, information indicating the margin of communication can be created by the same processing as those devices.

  Further, the information creating means can determine the margin of communication using the communication result in the preliminary communication process. Even if the RFID tag enters the communication area, if the communication margin is small, when the success rate of communication decreases due to the occurrence of noise, the number of preliminary communication processes increases, and the timing of transition to this communication process This is because there may be a delay. Therefore, if it is possible to estimate the timing when this tag enters the communication area from the moving speed of the RFID tag, or if it is possible to detect that the tag has reached the communication area using a sensor or the like, the timing coincides with the estimated timing or the detection timing. Thus, preliminary communication processing can be started, and the margin of communication can be determined based on the number of executions of the preliminary communication processing and the success rate.

  It should be noted that the margin when performing communication while moving the tag varies depending on the moving speed of the tag and the capacity of data transmitted to the tag, in addition to the distance between the tag and the antenna unit. Therefore, when the communication margin cannot be ensured, the adjustment can be performed by selecting one of the above factors.

  Further, the first to seventh read / write processing devices (including various aspects) can be provided with storage means for storing information indicating the margin of communication created by the information creation means. The notification means in this case is set to display or output at least one of the information immediately after created by the information creation means and the information stored in the storage means.

  In the above, the storage means can be constituted by a nonvolatile memory device and means for storing information indicating a margin of communication in the memory device. The means for storing the latter information can be set by incorporating a program in a computer constituting the control unit.

  According to the present invention, since the RFID tag read / write processing device has a function for displaying or outputting information that can grasp how much margin the communication process has, the RFID tag and the antenna unit When adjusting the distance, the moving speed of the tag, etc., it is possible to adjust the margin of communication based on this display and output. Accordingly, it is possible to stably perform the communication process with the RFID tag even in an environment where the fluctuation of the noise level is large.

  FIG. 1 shows a configuration of a reader / writer 1 for an RFID tag to which the present invention is applied and an RFID tag 2 (hereinafter simply referred to as “tag 2”) to be communicated with. The tag 2 of this embodiment is of a type that does not have a built-in power supply and operates by induced electromotive force generated by a transmission wave from the reader / writer 1, and includes a control unit 21 and a semiconductor memory 22. Further, the tag 2 is provided with an antenna coil 23, a capacitor 24, a load switch 25 (a resistor with a contact is used in this embodiment) and the like for communication. The control unit 21 of the tag 2 includes a peripheral circuit such as a demodulation circuit for demodulating a transmission signal from the reader / writer 1 in addition to the computer.

  The reader / writer 1 includes a control unit 10, an antenna coil 11, a transmission circuit 12, a reception circuit 13, an oscillation circuit 14, a Z conversion circuit 101 for matching processing for the antenna coil 11, and the like in a single housing (not shown). .) Built in. Further, the housing is provided with a display unit 15, an interface (I / F) circuit 16, an input / output (I / O) circuit 17, and the like.

  The control unit 10 on the reader / writer 1 side is a computer, and executes a communication process with the tag 2 and a test mode process to be described later based on a program incorporated in the internal memory. Further, the control unit 10 outputs a high-frequency pulse that is a source of a carrier wave based on the pulse signal from the oscillation circuit 14. Further, at the time of communication with the tag 2, data representing the contents of the command is output as a pulse signal (hereinafter, this output signal is referred to as “command signal”).

  The transmission circuit 12 includes a drive circuit 102, a modulation circuit 103, a tuning amplifier circuit 105, and two Z conversion circuits 104 and 106 sandwiching the tuning amplifier circuit. The receiving circuit 13 includes a band pass filter (BPF) circuit 107, a detection circuit 108, a low pass filter (LPF) circuit 109, an amplifier circuit 110, a comparator circuit 111, and the like.

  The display unit 15 includes a numerical display for displaying a success rate of communication, which will be described later, a plurality of indicator lamps (not shown), and the like, and is provided at an appropriate position on the surface of the housing. The interface circuit 16 is used for communication with a host device (not shown) such as a personal computer or a PLC. The input / output circuit 17 is used for taking in an external signal and outputting a processing result.

  FIG. 2 is a timing chart of signals related to transmission / reception of the reader / writer 1. FIG. 2 (1) shows a flow of signal processing related to command transmission to the tag 2, and FIG. The flow of signal processing related to reception is shown respectively.

  In FIG. 2A, (a) is the above-mentioned carrier wave, and (b) is a command signal. The command signal is a signal obtained by pulse-width modulating the data of each bit constituting the command with “1” being low level and “0” being high level.

  The modulation circuit 103 performs amplitude modulation (ASK modulation) on the carrier wave using the command signal, and generates a transmission signal as shown in (c) of the figure. This transmission signal is given to the antenna coil 11 through amplification processing by the tuning amplifier circuit 105 and impedance matching processing by the Z conversion circuits 104, 106, 101, and is transmitted to the tag 2 as electromagnetic waves.

  When the control unit 21 on the tag 2 side demodulates the transmission signal from the reader / writer 1 and recognizes the content of the command, the control unit 21 executes processing according to the command and generates a response indicating the processing result. In order to return this response, the control unit 21 turns on / off the load switch 25 based on the data arrangement as shown in (d) and (e) of FIG. In this embodiment, the length of the period for transmitting the signal for 1 bit is set to a length necessary for repeating the on / off of the load switch 25 16 times. When the data to be transmitted is “0”, on / off of the load switch 25 is repeated eight times in the first half of the period, and the load switch 25 is turned off in the second half. On the contrary, when the data to be transmitted is “1”, the load switch 25 is turned off in the first half of the period, and the on / off is repeated 8 times in the second half.

  When the antenna coil 1 and the tag 2 are in a communicable relationship, the antenna coils 11 and 23 are in an electromagnetically coupled state. Therefore, when the impedance of the tag 2 is periodically switched by switching the load switch 25 described above, the impedance of the reader / writer 1 also changes along with this switching, and the current flowing through the antenna coil 11 changes. The receiving circuit 13 detects a signal indicating the response from this change. After the noise is removed by the band-pass filter circuit 107, the detection circuit 108 extracts the carrier wave affected by the impedance switching. Further, after the frequency component of the carrier wave is removed by the low-pass filter circuit 109, the amplification process is performed by the amplifier circuit 110. As a result, a received signal as shown in (f) in the figure is detected.

  In the received signal, a wave having an amplitude greater than or equal to a predetermined value appears in synchronization with the switching during the period when the load switch 25 is switched. However, a wave having a predetermined amplitude also appears in the received signal during the period in which the load switch 25 is kept off due to the influence of ambient noise.

  The comparator circuit 111 compares the received signal with a predetermined reference level, and generates a binary signal from which a wave having a large amplitude is extracted, as shown in (g) of the figure. The control unit 10 demodulates the data of each bit as shown in (h) in the figure by dividing the binary signal for each bit.

  The reader / writer 1 receives a command (read command or write command) from the above-described upper device, thereby starting communication with the tag 2 and giving the tag 2 a command similar to that of the upper device. When the tag 2 executes processing according to this command and returns a response, the reader / writer 1 transmits this response to the host device.

  FIG. 3 is a flow of communication processing in the reader / writer 1, the tag 2, and the host device, where (1) shows the contents of signals exchanged between the host device and the reader / writer 1, and (2) shows The content of the signal transmitted from the reader / writer 1 to the tag 2 is shown, and (3) shows the content of the signal transmitted from the tag 2 to the reader / writer 1. In the figure, a portion indicated by a dotted line is an information processing period of the reader / writer 1 or the tag 2, and the content of specific processing is also shown in the margin of the figure for these periods.

Hereinafter, the flow of basic information processing for the tag 2 will be described with reference to the reference numerals (A, B, C...) In this figure.
First, the host device generates a command indicating processing to be executed by the tag 2 and transmits it to the reader / writer 1 (A). The reader / writer 1 analyzes the contents of this command and then sends a command requesting the first information read to the tag 2 (B). This first information reading is for confirming fixed data such as identification information of the tag 2 and is called “system read”. The tag 2 recognizes and analyzes the system read command, generates a response including the designated information, and returns it to the reader / writer 1 (C).

  When the reader / writer 1 analyzes the content of the response and determines that the response is a normal response, the reader / writer 1 transmits a second command to the tag 2 (D). The second command is intended to give the RFID tag 2 the contents of the command (A) from the host device and execute the command. Hereinafter, this command is referred to as an “execution command”. The tag 2 analyzes the execution command and executes a process corresponding to the content, generates a response indicating the content of the process, and returns the response to the reader / writer 1 (E). The reader / writer 1 confirms that the response from the tag 2 is normal, and transmits this to the host device (F).

  Note that the processing shown in FIG. 3 is executed after the tag 2 is stopped for a predetermined time in front of the reader / writer 1. When communicating without moving the tag 2, the system read of B is repeated until the response of C is obtained, and then the execution command transmission process of D is executed. In each embodiment shown in FIGS. 4 to 9 below, the processing of B and C is executed only for one cycle on the assumption that the tag 2 is stopped to perform communication.

  A reader / writer 1 and a tag 2 of a general RFID system repeatedly execute a B to F signal exchange for a plurality of cycles in response to a command from the device. Accordingly, in any of these communication processes, if a correct response can be obtained from the tag 2, the higher-level device can execute the intended information processing.

  However, when the margin of communication between the reader / writer 1 and the tag 2 is small, the difference between the signal indicating the original data and the noise is small. In such a case, if the noise level fluctuates due to sudden noise or the like, the tag 2 or the reader / writer 1 side cannot recognize the data and the noise separately, and finally the tag 2 May not be able to get a normal response.

  Therefore, in the embodiment shown below, the reader / writer 1 executes a test mode for checking the margin of communication. In this test mode, trial communication with the tag 2 is executed to obtain a success rate of communication, and this is displayed on the display unit 15. Based on this display, the user can adjust the distance between the reader / writer 1 and the tag 2 so that the communication is performed with a sufficiently high success rate, so that a sufficient communication margin can be secured. It is possible to cope with noise fluctuations.

  Details of the processing in the test mode will be described below with reference to FIG. In this embodiment, the exchange of the signals B to E in FIG. 3 is executed as one communication process and executed 100 times. In the figure, X is the number of communication processing executions (hereinafter referred to as “communication execution number X”), Y is the number of successful communication (hereinafter referred to as “success number Y”), P is the communication success rate, Each is shown.

  This process is also started based on a command from the host device (a command for commanding execution of the test mode), as in the normal read / write process shown in FIG. First, in the first ST1 (ST is an abbreviation for STEP (the same is true for the following)), the communication execution count X and success count Y are reset to zero. In the next ST2, the above-described system read is executed, and in ST3, the response from the tag 2 is received and analyzed. If it is determined that the response is normal, the process proceeds from ST4 to ST5, and an execution command is transmitted. In the next ST6, a response to the execution command is received, and processing for analyzing the content is executed. If it is recognized that the response is normal by this process, the process proceeds from ST7 to ST8, and the communication execution count X and success count Y are incremented.

  On the other hand, if either the response to the system read or the response to the execution command is defective, the process proceeds to ST9, and only the communication execution count X is incremented. If the response to the system read is not normally obtained, only ST9 is executed, and the execution command transmission process is skipped.

  After executing either ST8 or ST9, the process returns to ST2 via ST10. Then, the same processing as described above is executed again, and if the communication is successful, the success count Y is counted. When the communication process for 100 times is completed, ST10 becomes “YES” and the process proceeds to ST11. The ratio of the success count Y to the communication execution count X is obtained, and this value is set as the communication success rate P. In ST12, the value of the communication success rate P is displayed on the display unit 15.

  Therefore, the user temporarily sets the distance between the reader / writer 1 and the tag 2 and executes the test mode. If the displayed communication success rate P is equal to or greater than a predetermined value, it is considered that the communication margin has been secured. Thus, the temporarily set distance can be determined.

  In the above-described embodiment, the ratio of successful communication processing is obtained, but instead, the difference between the number of successful times Y with respect to the number of times of communication execution X may be obtained. In this case, it can be considered that the smaller the displayed numerical value, the greater the margin of communication.

  Further, instead of the communication success rate, a ratio of failed communication processing may be obtained. In the above embodiment, the communication success rate is displayed on the reader / writer 1 side. Instead, the communication success rate is output to the upper device, and the display processing is performed on the upper device side. Also good.

  In the following test mode embodiment, the communication process is repeated while gradually reducing the level of the transmission signal to the tag 2, and the communication margin is determined based on the level of the transmission signal when the communication process fails. Like to do. When this embodiment is applied, the reader / writer 1 is provided with a level adjustment circuit as shown in FIG.

  The level adjustment circuit 120 of FIG. 5 is a circuit in which three resistors R1, R2, and R3 are connected in parallel, and is interposed between the antenna coil 11 and the ground. Switching circuits SW1, SW2, and SW3 are connected to the resistors R1, R2, and R3, respectively, and the magnitude of the resistance changes depending on the combination of switching circuits that are turned on. On / off of each switching circuit SW1, SW2, SW3 is switched by the control unit 10. In FIG. 5, the switching circuits SW1, SW2, and SW3 are shown in a simplified manner, but it is actually desirable to use transistors, analog switches, and the like.

  The Q of the antenna coil 11 decreases as the resistance of the level adjustment circuit 120 increases, and the transmission level decreases as Q decreases. Therefore, the control unit 10 of this embodiment executes the communication process while changing the combination of the switching circuits to be turned on so that the resistance of the level adjustment circuit 120 increases stepwise.

  FIG. 6 shows an outline of a method for adjusting the distance between the reader / writer 1 and the tag 2 by adjusting the transmission level. In this FIG. 6 and the next FIG. 7, for the sake of simplicity, a maximum of 1 watt (W) of power can be generated for transmission to the tag 2, and by switching the resistance, Assume that power can be reduced by 0.2 W.

  The maximum distance that can be communicated with the tag 2 (hereinafter referred to as “communication possible distance”) is determined by whether or not the necessary power can be induced in the tag 2 by the transmission wave. Therefore, as the transmission level decreases, the communicable distance also decreases. In this embodiment, as shown in FIG. 6, if communication is possible until the transmission level reaches 0.4 W, the communicable distance when the distance between the reader / writer 1 and the tag 2 is 0.4 W. It is in a range that does not exceed L, and when the transmission level is set to the maximum 1 W, it is considered that a sufficient margin is secured for communication. Since the communicable distance varies depending on the ambient noise level, it must be confirmed in the test mode.

  In the test mode of this embodiment, using three indicator lamps that emit red, yellow, and green, an indication that communication processing is completely impossible (display indicating that communication is not possible) and communication are possible. However, a display indicating that a sufficient margin cannot be secured (communication unstable display) and a display indicating that the communication is possible with a sufficient margin (communication stable display) are performed. The user can easily determine whether or not the current communication is performed in an appropriate state with a sufficient margin depending on which display is performed.

  FIG. 7 shows a processing procedure in the test mode. In addition, W in a figure shows the electric power contained in a transmission signal, and a unit is a watt. Similar to the procedure of FIG. 4, this procedure is also started by a command from the host device. In the first ST21, the transmission level is set to the maximum value of 1.

  In the next ST22, system read is executed. In ST23, the response from the tag 2 is received and the content is analyzed. If it is determined that the response is normal, the process proceeds from ST24 to ST25, and an execution command is transmitted. In ST26, a response to the execution command is received and the content is analyzed. If this response is also normal, ST27 is “YES”, the process proceeds to ST28, and the transmission level is decreased by 0.2 W.

  Thereafter, the processing of ST22 to ST27 is performed again. In the same manner, success in receiving a response to both the system read and the execution command is regarded as successful communication, and each time communication is successful, the transmission level is decreased and the processes of ST22 to ST27 are executed.

  In the loop of ST22 to ST28, when a response to either the system read or the execution command is not normally obtained, ST24 or ST27 is “NO”. As a result, the control unit 10 exits the loop and checks the transmission level at that time.

  Here, if the transmission level is 1, which is the initial value, ST29 is “YES”, the process proceeds to ST31, and a red indicator lamp is lit as a communication impossible display. If the transmission level is less than 1 but greater than 0.4, ST29 is “NO” and ST30 is “YES” and the process proceeds to ST32, and a yellow indicator lamp is lit as a communication unstable display. If the transmission level is 0.4 W or less, both ST29 and ST30 are “NO” and the process proceeds to ST33, and a green indicator lamp is lit as a stable communication display.

  Therefore, the user can temporarily set the distance between the reader / writer 1 and the tag 2 to execute the test mode, and can determine the distance when the green indicator light is turned on as an appropriate distance. In normal times, the maximum transmission level of 1 W is always set, so that communication can be performed with a sufficient margin.

  In the above embodiment, the communication process is performed while changing the transmission level, but instead, the amplification factor of the received signal may be changed. FIG. 8 shows an example in which the amplification circuit 110 is provided with an amplification factor adjustment function. 110A in the figure is an operational amplifier which forms the main body of the amplifier circuit 110, and an amplification factor adjustment circuit 121 is provided in the feedback path. The adjustment circuit 121 also includes three resistors R1, R2, and R3 and switching circuits SW1, SW2, and SW3 that individually correspond to the resistors R1, R2, and R3, similarly to the level adjustment circuit 120 of FIG. On / off of each switching circuit SW1, SW2, SW3 is controlled by the control unit 10 as in the example of FIG.

  In the test mode of this embodiment, the control unit 10 sets the amplification factor to the maximum value and executes the communication process. If the communication is successful, the control unit 10 changes the amplification factor to a small value by a predetermined value. Thereafter, the communication process is repeated while decreasing the amplification factor stepwise according to the procedure according to FIG. 7, and the amplification factor at the time when the communication fails is checked. If this amplification factor remains the initial value, a communication impossible display is performed. If the amplification factor is smaller than the initial value but higher than a predetermined threshold value, a communication unstable display is performed. On the other hand, if the amplification factor is equal to or less than the threshold value, a stable communication display is executed on the assumption that a sufficient margin is secured for the communication.

  As shown in (f) of FIG. 2 (2), in the received signal detected by the receiving circuit 13, the period during which data transmission from the tag 2 is not performed (the off state of the load switch 25 is maintained). Level change reflecting noise. If the amplification factor is set sufficiently, the noise level and the original data can be separated, but the separation becomes difficult as the amplification factor becomes smaller. However, if communication is possible until the amplification factor is close to the threshold value, it can be considered that a communication margin sufficient to cope with noise can be secured. The user executes the above-described test mode while adjusting the distance between the reader / writer 1 and the tag 2 and determines the distance when the green indicator lamp, which is a stable communication display, is turned on as appropriate. Also in this case, since the amplification factor during the normal processing is set to the maximum value, it becomes possible to stably perform communication.

  When communication processing is performed while changing the transmission level and amplification factor as in the above two examples, the number of changes is counted, and the indicator lamp is controlled with the count value at the time of communication failure. Also good. That is, if the count value is 0, the communication impossible display is executed, and if the count value is larger than 0 and smaller than the predetermined threshold value, the communication unstable display is executed, and the count value is equal to or larger than the threshold value. For example, a stable communication display can be executed.

  The embodiment shown in FIG. 9 is a combination of the procedure shown in FIG. 4 and the procedure shown in FIG. First, after the transmission level is set to the maximum value of 1 W in the first ST41, in ST42 to ST51, the same processing as ST1 to ST10 in FIG. 5, that is, the communication processing for 100 times is executed. Thereafter, in ST52, a communication success rate P is obtained. If P is greater than or equal to a predetermined value (0.98 in the illustrated example), ST53 becomes “YES” and the process proceeds to ST54, where the transmission level is decreased by 0.2.

  Thereafter, the process returns to ST42, and the communication process is executed 100 times again under the changed transmission level. Similarly, when a communication success rate P of 0.98 or more is obtained, it is regarded as a communication success, and the transmission level is changed and the process is continued.

  When the communication success rate P at a predetermined time becomes smaller than 0.98, ST53 becomes “NO”. In response to this “NO” determination, the control unit 10 selects any one of the communication impossible display, the communication unstable display, and the communication stable display based on the transmission level at that time, similarly to ST29 to ST33 in FIG. Are executed (ST55 to ST59). Note that the same control as in FIG. 9 can also be executed when the amplification factor of the received signal is changed instead of the transmission level.

  According to the above embodiment, since the communication margin can be checked when the accuracy of the communication processing falls below a certain level, the adjustment of the positional relationship between the reader / writer 1 and the tag 2 is performed as shown in FIG. This can be performed with higher accuracy than the embodiment. Therefore, communication can be performed in a more stable state, and information processing resistant to noise can be realized.

Note that each of the embodiments of the test modes described above is started when a command for starting the test mode is received from the host device, but is not limited thereto. For example, a test mode changeover switch may be provided on the reader / writer 1 side so that the test mode is executed independently of a command from a host device.
In each embodiment, in one communication process, two types of commands, that is, a system read command and an execution command are transmitted and a response to each command is received. One communication process may be performed by sending one command and receiving a response to the command.

  Next, a test mode in the case of checking the margin of communication on the assumption that communication is performed while moving the tag 2 will be described.

  FIG. 10 shows a state before the tag 2 enters the communication area 200, and FIG. 11 shows a state where the tag 2 passes through the communication area 200. At the time shown in FIG. 10, even if a command is sent from the reader / writer 1 to the tag 2, the tag 2 cannot respond to the command, and therefore a normal response is not returned. On the other hand, as shown in FIG. 11, when the tag 2 enters the communication area 200, power necessary for communication is induced in the RFID tag 2 and a command from the reader / writer 1 can be received. Thereafter, the tag 2 moves along the direction of the arrow F in the communication area 200, but commands and responses can be exchanged until the tag 2 leaves the communication area 200.

  In the test mode in which communication is performed while the tag 2 is moved, it is necessary to detect that the tag 2 has entered the communication area 200 and can communicate. For this reason, in this embodiment, the above-described system lead (shown in FIG. 3B) is repeatedly transmitted, and a normal response from the tag 2 to the system lead (shown in FIG. 3C) is sent. The execution command transmission process is started on the condition that it has been received.

  Further, in the test mode of this embodiment, instead of the process of transmitting a normal execution command, a dedicated execution command (hereinafter, this command is referred to as “test command”) whose data capacity is limited to 1 byte is transmitted. Like to do. This test command also instructs the tag 2 to read or write data in the same manner as a normal execution command, and a response corresponding to the command is returned from the tag 2.

  Hereinafter, a detailed processing procedure in the test mode will be described with reference to FIG. In the figure, Z is the number of times of communication execution, and U is the number of times of receiving a normal response to the transmission of the test command (hereinafter, this U is referred to as “the number of successful communication”). Also. Q in ST72 is a margin of communication.

  Prior to executing this procedure, the data capacity of a normal execution command is input to the control unit 10 from a host device or the like. In ST61, this data capacity is set to a variable m, this m is multiplied by a standard number of transmissions (10 in this embodiment), and the multiplied value is set to a variable N.

  Next, in ST62, the communication execution count Z and the success count U are reset to zero, and then system read is executed (ST63). In the next ST64, a response to the system lead is received and analyzed. Here, when a normal response cannot be confirmed, ST65 becomes “NO”, the process returns to ST63, and the system read is re-executed. When a normal response is confirmed as a result of executing the system read a predetermined number of times in this way, ST65 becomes “YES”, and the process proceeds to a loop of ST66 to 71.

  In ST66 to 71, the test command transmission process for one byte and the response reception and confirmation process for the command are repeated N times in the same procedure as ST4 to 10 in FIG. In addition, in the N times of communication, every time a normal response is confirmed, the communication success number U is incremented.

  According to the flow up to the above, by repeatedly executing the system read until a normal response is obtained, it is detected whether or not the tag 2 has entered the communication area, and a test command is transmitted in response to the detection. Can start. Further, by transmitting the test command N times, the same amount of data as when the actual execution command is transmitted the standard number of times (10 times) can be transmitted to the tag 2.

  When the loop of ST66 to 71 is executed N times, ST71 becomes “YES” and the process proceeds to ST72. In ST72, the successful communication count U is divided by the data volume m of the normal execution command, and the calculation result is set as the margin Q.

When the communication margin Q is obtained in this manner, in ST73, the calculated margin Q is displayed and output to an external device.
Thereafter, when the test is continued using another tag 2, ST74 becomes “YES”, and the process returns to ST62. Therefore, the margin Q can be obtained for each tag 2.

  When the communication process is performed while the tag 2 is moved, since the communication time is limited, it is difficult to perform the communication process a sufficient number of times as in the case where the communication is performed with the tag 2 stopped. In particular, when the data capacity of the execution command is large, the number of possible communications decreases. In this case, if communication fails due to the influence of noise, it may be difficult to execute the required number of communication processes.

  Since the success count U in the above embodiment is the number of successful communications using a 1-byte command that is the minimum information unit, the value of U is transmitted to the tag 2 while the tag 2 passes through the communication area 200. It can be thought of as representing the data capacity that can be done. Since the margin Q of ST72 is obtained by dividing U by the data volume m of the execution command, the number of times that the execution command can be transmitted to the tag 2 (hereinafter referred to as “the number of times the command can be transmitted”). It can be thought that it represents. Therefore, the user can easily confirm whether or not the communication process can be executed as many times as necessary based on the margin Q obtained in the test mode of FIG.

  If the user determines that the margin Q is not appropriate, the user can adjust the moving speed of the tag 2 in addition to the distance between the reader / writer 1 and the tag 2. If possible, the margin can be improved by adjusting the data capacity of the execution command.

  Furthermore, the numerical value output as the margin Q is not limited to the number of times the command can be transmitted, but may be a value of U, that is, a data capacity that can be transmitted to the tag 2. Further, a communication success rate similar to that in the embodiment of FIG. 4 may be obtained.

  By the way, in each Example demonstrated so far, although it can apply to the reader / writer 1 with which the antenna part and the control part which has a function of a reading / writing process were integrated, it separated from the antenna part not only in this. It can also be applied to a controller.

FIG. 13 shows an example of a controller separated from the antenna unit.
In the housing 30 of the controller 3, the control unit 10, the interface circuit 16, and the input / output circuit 17 of the configuration shown in FIG. A plurality of connectors, a numerical indicator 31, an indicator lamp 32, and the like are provided on the upper surface of the housing 30.

  Of the various connectors, 33 and 34 are for connection to an antenna unit (not shown). Reference numerals 35, 36, and 37 denote connectors for connecting to a host device such as a personal computer or PLC. Reference numeral 38 denotes a connector for outputting numerical information related to the margin of communication to the host device.

  The numerical display 31 is used to display numerical values such as the communication success rate P and the margin Q described above. The plurality of indicator lamps 32 below display the numerical values classified into a plurality of levels, or display the stability of communication by processing according to the embodiment of FIGS. Used for, etc.

  Note that a non-volatile memory can be incorporated in the reader / writer 1 and the controller 3 described above. In this case, the margin created in the test mode is accumulated in the non-volatile memory, and this accumulated information can be read in accordance with, for example, a command from the host device and output to the host device. With such a function, the user can confirm the margin of communication in the test mode executed in the past and the change over time.

  Note that the process of reading the accumulated information is not limited to the case where it is executed in response to a command from a higher-level device. For example, each time a test mode execution command is received from the above device, a response including information created in the test mode or accumulated information for a predetermined period in the past may be created and transmitted to the host device.

It is a block diagram which shows the structure of the reader / writer to which this invention was applied, and the tag of the communication object. 6 is a timing chart of signals related to transmission / reception of a reader / writer. It is a timing chart which shows the flow of the communication process in a reader / writer, a tag, and a high-order apparatus. It is a flowchart which shows the example of the process sequence of test mode. It is a figure which shows the example of a transmission level adjustment circuit. It is a figure which shows the outline | summary of the method of adjusting distance by adjustment of a transmission level. It is a flowchart which shows the process sequence of the test mode in the case of applying the method of FIG. It is a figure which shows the example of the adjustment circuit of an amplification factor. It is a flowchart which shows the example of the process sequence of test mode. It is a figure explaining the state before a tag enters a communication area. It is a figure explaining the state which the tag entered into the communication area. It is a flowchart which shows the process sequence of the test mode in the case of communicating while moving a tag. It is a perspective view which shows the external appearance of the controller isolate | separated from the antenna part.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Reader / writer 2 RFID tag 3 Controller 10 Control part 11 Antenna coil 15 Display part 31 Numerical display 32 Indicator lamp 38 Connector 120 Transmission level adjustment circuit 121 Gain adjustment circuit

Claims (10)

An apparatus for communicating with an RFID tag including a semiconductor memory to read / write information from / to the semiconductor memory,
Communication processing means for executing communication processing with the RFID tag;
Information creating means for creating information indicating a margin of communication based on the communication performance of the communication processing means;
A read / write processing device for an RFID tag, comprising: information means for displaying or outputting information indicating a margin of communication created by the information creating means.   The information creating means counts the number of successful or unsuccessful communications while the communications processing means executes a plurality of communications processes, and obtains a margin of communications based on the counted value. Read / write processing device for the described RFID tag. Transmission level adjusting means for adjusting the level of a transmission signal to the RFID tag;
Control means for controlling the operation of the communication processing means while adjusting the transmission level using the transmission level adjusting means;
Determining means for determining whether or not communication with the RFID tag can be appropriately executed based on a processing result of the communication processing means;
The control means starts the communication processing means with the RFID tag in a state where the level of the transmission signal is set to a certain value, and then repeatedly executes the communication processing while the determination means In response to determining that the communication can be properly performed, the level of the transmission signal is changed to a value lower than the current value,
The information creating means is information indicating a margin of the communication based on the level of the transmission signal at the time when the determination means determines that the communication cannot be properly executed or the number of times the level of the transmission signal has been changed up to that time. The read / write processing device for an RFID tag according to claim 1, wherein Transmission level adjusting means for adjusting the level of a transmission signal to the RFID tag;
Control means for controlling the operation of the communication processing means while adjusting the transmission level using the transmission level adjusting means,
The control means causes the communication processing means to execute communication processing of two or more predetermined cycles, and changes the level of the transmission signal to a value lower than the current value every time one cycle of communication processing is completed. ,
When the communication processing for the predetermined number of cycles is completed, the information creating means is based on how far the predetermined number of cycles have been properly executed, or when the communication is appropriately executed. The read / write processing device for an RFID tag according to claim 1, wherein information indicating a margin of the communication is created based on a minimum value of a transmission signal level. A reception gain adjusting means for adjusting an amplification factor of a signal received from the RFID tag;
Control means for controlling the operation of the communication processing means while adjusting the amplification factor of the received signal using the reception gain adjusting means;
Determining means for determining whether or not communication with the RFID tag can be appropriately executed based on a processing result of the communication processing means;
The control means starts the communication processing means with the RFID tag in a state where the amplification factor is set to a certain value, and then repeatedly executes the communication processing while the determination means performs communication. In response to determining that it can be properly executed, the gain of the received signal is changed to a value lower than the current value,
The information creating means includes information indicating a margin of the communication based on the amplification factor of the received signal at the time when the determination device determines that the communication cannot be properly performed or the number of times the amplification factor has been changed so far. The read / write processing device for an RFID tag according to claim 1 to be created. A reception gain adjusting means for adjusting an amplification factor of a signal received from the RFID tag;
Control means for controlling the operation of the communication processing means while adjusting the gain of the received signal using the reception gain adjusting means,
The control means causes the communication processing means to execute communication processing of a predetermined number of cycles of 2 or more, and changes the amplification factor to a value lower than the current value every time the communication processing for one cycle is completed,
When the communication processing for the predetermined number of cycles is completed, the information creating means is based on how far the predetermined number of cycles have been properly executed, or when the communication is appropriately executed. The read / write processing device for an RFID tag according to claim 1, wherein information indicating a margin of the communication is created based on a minimum value of a gain of a received signal.   The discriminating unit counts the number of successful or failed communications in the predetermined number of communication processes each time the communication processing unit executes two or more predetermined number of times of communication processing, and based on the count value, The RFID tag read / write processing device according to claim 3, wherein it is determined whether or not the communication can be appropriately executed. The communication process for one cycle executed by the communication processing means includes a plurality of communication processes with the RFID tag,
In the communication processing for each cycle, the information creating means appropriately counts the communication for each cycle based on the counting means for counting the number of successful or failed communications in that cycle, and the count value obtained by the counting means. 7. A read / write process for an RFID tag according to claim 4, further comprising: a discriminating unit that discriminates whether or not the information has been generated, and generating information indicating a margin of the communication using a discrimination result of the discriminating unit for each cycle. apparatus. The communication processing executed by the communication processing means includes preliminary communication processing with the RFID tag,
Controls the operation of the communication processing means so that the preliminary communication process is repeatedly executed, the main communication process is performed in response to the success of the preliminary communication process, and the main communication process is repeatedly executed for a predetermined cycle. The read / write processing device for an RFID tag according to claim 1, further comprising a control unit that performs the control. Further comprising storage means for storing information indicating the margin of communication created by the information creating means;
The RFID tag for the RFID tag according to any one of claims 1 to 9, wherein the notification unit displays or outputs at least one of information immediately after being created by the information creation unit and information stored in the storage unit. Read / write processing device.

Images