KR20070093148A - Reader control device, reader control method, and control program - Google Patents

Abstract

A read accuracy statistic information DB (105) contains read accuracy statistic information indicating a read history when a reader/writer (106) has read RFID tags A to E in the past. When a self tuning unit (102) causes the reader/writer (106) to read tags A to E, the self tuning unit (102) decides a read condition of the reader/writer (106) according to the read accuracy statistic information stored in the read accuracy statistic information DB (105) and causes the reader/writer (106) to read the tags according to the read condition decided. The reader/writer (106) transmits the tag read result to a filtering unit (103). The filtering unit (103) accumulates the read result received as a history in the read accuracy statistic information DB (105).

Description

READER CONTROL DEVICE, READER CONTROL METHOD, AND CONTROL PROGRAM}

The present invention relates to a control device for controlling a reader / writer for reading an RFID tag.

In the reading of an RFID tag in the conventional RFID (Radio Frequency IDentification) technique, the following technique is disclosed. That is, as a method of increasing the reading efficiency, a method of attaching a plurality of tags to each surface of the object and moving the reader / writer to a position suitable for the angle of the surface has been proposed (for example, Patent Document 1). In this prior art, the radio wave characteristic that the range in which the RFID tag can be read / written is long in the vertical direction of the antenna face of the reader / writer is used. Specifically, a method of rotating the reader / writer in a direction most suitable for reading / writing has been proposed. In addition, a method of arranging a plurality of readers / writers in advance orthogonal to each other and selecting a reader / writer suitable for the position of a tag to be read / written is proposed.

As described in Patent Document 1 described above, in a system such as a factory, when there is a means for automatically moving a reading device such as an attached tag or a reader / writer or an antenna attached to the reader / writer device, one side may be placed in a positional relationship suitable for tag reading. Or it can be considered that if both are moved, it can be read relatively accurately.

However, it is difficult to think that the tag attachment always returns to the same position and the same direction when the RFID tag is attached to and managed by a general consumer's hand in a display stand of a store. Therefore, it is difficult to move the reading device to their position automatically. For this reason, the fixed reading apparatus provided so that the whole display stand may be covered in a readable range is used.

In this case, the accuracy of tag reading varies considerably depending on the position, direction in which the tag is installed, and the surrounding situation at that time. In addition, a weak radio wave is used to read the RFID tag. Therefore, even if human beings were in exactly the same environment, the surrounding radio wave situation was slightly changed. Under the influence, a tag can be read and a read fails.

In a system using RFID, when reading of an RFID tag fails, it is not possible to distinguish whether it is a read miss according to the radio wave situation or whether the tag is not actually within the readable range. For this reason, it is common to determine that the tag does not exist when the same RFID tag is continuously read a plurality of times by specifying the number of times or the time, and it cannot be read once.

Therefore, in the conventional system using RFID, the number of readings increases, and time is required for reading in order to secure sufficient reading accuracy. In addition, when the preset number of reads is small, read misses may occur.

(Patent Document 1) Japanese Unexamined Patent Publication No. 2001-134724 (3rd to 8th pages, FIGS. 1 and 2)

(Tasks to be solved by the invention)

An object of the present invention is to improve reading efficiency and to improve reading accuracy when reading an RFID tag.

(Means to solve the task)

A reading device control device of the present invention is a reading device control device that controls a reading device that reads the information by communicating with a plurality of information storage devices that store predetermined information, wherein at least one of the plurality of information storage devices. A read request receiving section for receiving a read request for requesting the reading of the read request, a read history storing section for storing a read history in which the reading device has read each of the plurality of information storage devices in the past, and the read request receiving section. A reading condition for reading the reading object representing the information storage device according to the reading request to the reading device is determined based on the reading history stored in the reading history storage unit, and is read to the reading device according to the determined reading condition. And a read condition determiner for reading the read object. All.

The reading device control device is further configured to receive a reading result from the reading device in which the reading device reads the reading object in accordance with the reading condition, and to receive the read result in the reading history storage unit as the reading history. And a history control unit for storing the memory.

The reading condition determination unit notifies the history control unit of the determined read condition, and the history control unit stores the read condition notified from the read condition determination unit as the read history in the read history storage unit. do.

The read history stored in the read history storage section includes a number of reads that the read device has read to each of the plurality of information storage devices and a success number of successful reads among the number of reads, and the read condition determiner The number of readings when the reading apparatus reads the reading object is determined as the reading condition.

When the read condition determining unit determines the read count as the read condition, the read condition determiner calculates a success probability that the read succeeds from the read count and the success count included in the read history and based on the calculated success probability. And the number of readings is determined.

The reading device is movable and the position can be controlled, and the reading history stored in the reading history storage unit is read by the reading device for each of the plurality of information storage devices. And a read position of the read device, wherein the read condition determiner determines, as the read condition, the read position of the read device when the read device reads the read target.

The reading condition determining unit determines, as the reading condition, a plurality of reading positions of the reading device when the reading device reads the reading target.

The read history stored in the read history storage section further includes a number of reads at the read position and a success number of successful reads among the read counts, and the read condition determiner is used as the read condition. The reading position of the reading device in reading the reading object and the number of readings in the reading device reading the reading object at the reading position are determined.

The read history stored in the read history storage unit is first existence situation information indicating a presence situation of each of the plurality of information storage devices when the reading device reads each of the plurality of information storage devices. Wherein the reading condition determination unit determines each existence situation of the plurality of information storage devices from an existence situation determination system that grasps the existence situation of each of the plurality of information storage devices when the reading condition is determined. And acquires the second existence situation information to be indicated and determines the reading condition based on the first existence situation information included in the reading history and the second existence situation information acquired from the existence situation identifying system. .

The read history stored in the read history storage section includes a number of reads that the read device has read to each of the plurality of information storage devices and a success number of successful reads among the number of reads, and the read condition determiner And the second existence situation information acquired from the existence situation determining system, the first existence situation included in the reading history, the number of readings included in the reading history, and the number of successes included in the reading history. On the basis of this, the number of readings when the reading device reads the information storage device is determined as the reading condition.

The read history stored in the read history storage section includes a transmission output of the read device when the read device reads each of the plurality of information storage devices, and the read condition determination unit reads the read condition. As a condition, the reading apparatus determines the transmission output of the reading apparatus in the case of reading the reading object.

A reading device control device of the present invention is a reading device control device that controls each of a plurality of reading devices that read the information by communicating with a plurality of information storage devices that store predetermined information, wherein the plurality of information storage devices. A read request receiving unit for receiving a read request for requesting reading of at least one of the apparatuses, a read history storage unit for storing a read history of each of the plurality of reading apparatuses reading the plurality of information storage apparatuses in the past; Determine at least one reading device for reading a read object representing the information storage device according to the read request received by the read request receiving unit from the plurality of reading devices based on the read history stored in the read history storage unit; And read condition determination for reading the read object to the determined read device. It is characterized by having a part.

The reading device control device is further configured to receive, from the reading device, a reading result in which the reading device determined by the reading condition determining unit reads the reading target, and receives the read result as the reading history, as the reading history storage unit. It is characterized by including a history control unit for storing in the.

The reading condition determining unit determines a plurality of reading devices for reading the reading object from among the plurality of reading devices, and makes the determined plurality of reading devices read the reading object.

The read request receiving unit receives a read request for requesting reading of two or more information storage devices as the read object, and the read condition determining unit determines at least one of the plurality of read devices for each read object. It features.

A reading device control method of the present invention is a reading device control method for controlling a reading device that reads the information from a plurality of information storage devices storing predetermined information, wherein the reading device is each of the plurality of information storage devices. Stores a reading history of reading the data in the past, receives a read request for requesting reading of at least one of the plurality of information storage devices, and reads a read object representing the information storage device according to the received read request. A reading condition for reading in the device is determined based on the reading history, and the reading device is read in according to the determined reading condition.

The control program of the present invention is a control program for controlling the reading device in a reading device control device that controls the reading device that reads the information from a plurality of information storage devices that store predetermined information, wherein the reading device comprises: A process of storing a reading history of reading each of the plurality of information storage devices in the past, a process of receiving a read request for requesting reading of at least one of the plurality of information storage devices, and the received read request. A reading condition for reading a reading object representing the information storage device according to the reading device, based on the reading history, and processing the reading device to read the reading object in accordance with the determined reading condition. It is characterized by making it to a control apparatus.

(Effects of the Invention)

According to the present invention, the reading efficiency in the case of reading the RFID tag can be improved. In addition, the read accuracy can be improved.

1 is a diagram showing the configuration of an RFID tag reading system 1000 according to the first embodiment.

2 is a diagram showing an example of the appearance of the RFID tag read control device 100 according to the first embodiment;

3 is a diagram showing an example of a hardware configuration of the RFID tag read control device 100 according to the first embodiment;

4 is a flowchart of the operation of the RFID tag read control device 100 of Embodiment 1;

5 is a view showing the flow of information inside the RFID tag read control device 100 of the first embodiment,

6 is a flowchart of the operation of the self tuning unit 102 of the first embodiment,

7 is a diagram showing read precision statistics information stored in the read precision statistics information DB 105 according to the first embodiment;

8 is a view showing an aggregation result by the self-tuning unit 102 of the first embodiment,

9 is a table showing the reading accuracy in the case where the number of readings of Example 1 is equalized;

10 is a table for explaining a method for calculating the number of reads of Example 1;

11 is a view showing a calculation result of the number of readings of the first embodiment;

12 is a diagram showing the configuration of the RFID tag reading system 2000 of the second embodiment;

FIG. 13 is a diagram showing read precision statistics information stored in the read precision statistics information DB 205 according to the second embodiment; FIG.

14 is a table showing the results of reading the tag C by the reader / writer 206 of the second embodiment;

15 is a graph of the table of FIG. 14;

16 is a diagram showing the configuration of the RFID tag reading system 3000 of the third embodiment;

17 is a diagram showing read precision statistics information stored in the read precision statistics information DB 305;

18 shows a search result of tag B which the self-tuning unit 302 of Example 3 searches for and reads the read precision statistical information DB 305,

19 is a diagram showing the configuration of the RFID tag reading system 4000 of the fourth embodiment;

20 is a diagram showing read precision statistics information stored in the read precision statistics information DB 405 of the fourth embodiment;

21 is a diagram showing the configuration of the RFID tag reading system 5000 of the fifth embodiment;

FIG. 22 is a diagram showing read precision statistics information stored in the read precision statistics information DB 505 of the fifth embodiment.

Explanation of symbols for the main parts of the drawings

11, 12, 13, 14: control data 21, 22, 23, 24: read data

31, 32, 33: statistical data

100: RFID tag reading control device

101: application interface unit 102: self-tuning unit

103: filtering unit 104: reader interface unit

105: read accuracy statistical information DB 106: reader / writer

107 application program

108a, 108b, 108c, 108d, 108e: RFID Tag

121: CRT display device 122: K / B

123: mouse 124: CDD

127: FDD 130: LAN

140: system unit 141: ROM

142: RAM 143: communication board

150: magnetic disk device 151: OS

152: Window system 153: Program group

154: file group

200: RFID tag readout control device

201: application interface unit 202: self-tuning unit

203: filtering unit 204: reader interface unit

205 read accuracy statistics information DB 206: reader / writer

207: application program 208: RFID tag group

209 rail

211, 212, 213, 214: control data

221, 222, 223, 224: readout data 231, 232, 233: statistical data

300: RFID tag readout control device

301: application interface unit 302: self-tuning unit

303: filtering unit 304: reader interface unit

305: read precision statistics information DB

306a, 306b, 306c, 306d: Reader / Writer Device

307: application program 308: RFID tag group

311, 312, 313, 314: control data

321, 322, 323, 324: Reading data 331, 332, 333: Statistical data

400: RFID tag readout control device

401: application interface unit 402: self-tuning unit

403: filtering unit 404: reader interface unit

405: read precision statistical information DB 406: reader / writer

407: application program 408: RFID tag group

411, 412, 413, 414: control data

421, 422, 423, 424: read data

431, 432, 433, 434: statistical data

4001: Loan System 4002: Inventory Information DB

500: RFID tag readout control device

501: application interface unit 502: self-tuning unit

503: filtering unit 504: reader interface unit

505: Reading precision statistical information DB 506: Reader / Writer device

507 application program 508 RFID tag group

511, 512, 513, 514: control data

521, 522, 523, 524: Reading data 531, 532, 533: Statistical data

1000, 2000, 3000, 4000, 5000: RFID Tag Reading System

(Example 1)

Example 1 is demonstrated using FIGS. Embodiment 1 relates to an RFID tag reading control device (an example of a reading device control device) that controls a reader / writer device (an example of a reading device) that reads data of a plurality of RFID tags (an example of an information storage device). The RFID tag read control device according to the first embodiment holds a read history in which the reader / writer device has read each of a plurality of RFID tags in the past, and reads a predetermined RFID tag into the reader / writer device based on the read history held by the reader / writer device. Read conditions for the control. Then, the reader / writer device reads a predetermined RFID tag according to the determined read condition.

1 shows a configuration of an RFID tag reading system 1000 according to the first embodiment. As shown in FIG. 1, the RFID tag reading system 1000 includes an RFID tag reading control device 100, a reader / writer 106, and a tag group 108 of RFID tags A to RFID tags E. FIG. . In addition, the RFID tag reading control device 100 exchanges with the application program 107.

(1) The RFID tag read control device 100 controls the reader / writer device 106 and causes the reader / writer device 106 to read information stored in at least one of the tags A to E.

(2) The reader / writer device 106 includes a communication function and an antenna (not shown) for communicating with RFID tags A to RFID tags E (hereinafter, simply referred to as tags A, tags B, and the like).

(3) The tags A to E store predetermined information. The tags A to Tag E become "read objects" to which the stored information is read by the reader / writer device 106.

(4) The application program 107 calls a command of the RFID tag read control device 100.

In FIG. 1, the reader / writer device 106, the device for executing the application program 107, and the RFID tag read control device 100 are different devices from each other. The RFID tag read control device 100 exchanges data with a device that executes the reader / writer device 106 and the application program 107 by any communication means. But it is not limited to this. The program portion of the reader / writer device 106 and the application program 107 may be programs stored and executed in a computer that is the RFID tag read control device 100. The effect that can be obtained does not change from the configuration of FIG. 1, the RFID tag read control device 100 and the reader / writer device 106 are shown as different devices. However, it may be a device in which the RFID tag read control device 100 and the reader / writer device 106 are integrated.

FIG. 2 is a diagram illustrating an example of an appearance of the RFID tag read control device 100 shown in FIG. 1. 2 is an example of an appearance, the RFID tag reading control device 100 is displayed as a desktop computer. For example, when the RFID tag read control device 100 is integrated with the reader / writer device 106 as described above, the device in which the system unit 140 of FIG. 2 is miniaturized can be inserted into the reader / writer device 106. have.

In FIG. 2, the RFID tag reading control device 100 includes a system unit 140, a CRT (Cathode Ray Tube) display device 121, a keyboard (K / B) 122, a mouse 123, and a compact disc device. (CDD) 124 and a printer device 125 are provided. These are connected by cables. The RFID tag read control device 100 is connected to the reader / writer device 106 via a local area network (LAN) 130. Although it is wired in a figure, you may be a wireless LAN. In addition, although the RFID tag read control apparatus 100 and the reader / writer device 106 are connected via LAN, this is an example. The RFID tag read control device 100 and the reader / writer device 106 may be directly connected or may be connected via the Internet. It may be any connection type. The RFID tag read control device 100 is connected to the Internet 132.

3 is a hardware configuration diagram of the RFID tag read control device 100 shown in FIG. 2. In FIG. 3, the RFID tag read control device 100 includes a central processing unit (CPU) 160 that executes a program. The CPU 160 passes through the bus 161 to the ROM 141, the RAM 142, the CRT display 121, the K / B 122, the mouse 123, the communication board 143, and the FDD (Flexible). Disk Drive) 127, CDD 124, printer device 125, and magnetic disk device 150 are connected.

The communication board 143 is connected to the reader / writer device 106 via the LAN 130. For example, the communication board 143, the K / B 122, the FDD 127, etc. are an example of the information input part which inputs information. In addition, for example, the communication board 143, the CRT display apparatus 121, etc. are an example of the output part which outputs information,

In the magnetic disk device 150, an operating system (OS) 151, a window system 152, a program group 153, and a file group 154 are stored. The program group 153 is executed by the CPU 160, the OS 151, and the window system 152.

The program group 153 stores a program that executes a function described as "to-part" in the description of the embodiments described below. The program is read by the CPU 160 and executed. In the file group 154, what is described as "reading precision statistical information" is stored as "file" in the description of the embodiments to be described below.

In addition, what is described as "-part" in description of the Example demonstrated below may be implement | achieved by the firmware memorize | stored in ROM 141. FIG. Alternatively, the software may be implemented only in hardware, only in hardware, or in combination with software and hardware, or in combination with firmware.

In addition, the program for implementing the embodiments described below further includes a magnetic disk device 150, a flexible disk (FD), an optical disk, a CD (compact disk), an MD (mini disk), a DVD (Digital Versatile Disk), and the like. It may be stored by using a recording device by another recording medium of.

The configuration of the RFID tag read control device 100 will be described using FIG. 1. As shown in FIG. 1, the RFID tag read control device 100 includes an application interface unit 101 (an example of a read request receiver), a self-tuning unit 102 (an example of a read condition determiner), and a filtering unit ( 103) (an example of a history control unit), a reader interface unit 104, and a read precision statistical information DB (Data Base: database) 105 (an example of a read history storage unit).

The function of each structural element displayed as "-part" by the RFID tag read control apparatus 100 is demonstrated.

(1) The application interface unit 101 receives, from the application program 107, a "read command" (an example of a read request) for requesting reading of at least one of the tags A to E. The self-tuning unit ( A read command is issued to 102). In addition, the application interface unit 101 receives the "result of reading" from the filtering unit 103 and returns it to the application program 107.

(2) The self tuning unit 102 receives a "read command" from the application interface unit 101 and issues a "read command" to the reader interface unit 104. When issuing a "read command", the self-tuning unit 102 refers to the read precision statistical information DB 105 to read the number of times each tag A to tag E to be read, the order of reading, the reading time, and the like. The "reading parameter" (an example of reading condition) such as (continue reading for a predetermined time) is determined. Then, the "read command" is issued to the reader interface unit 104 together with the determined "reading parameter". The method of determining the "reading parameters" varies depending on the requirements of the system. For example, in some systems, the "number of reads" is determined as a "reading parameter". In the case of other systems, the "reading order of tags" is determined as the "reading parameter". In Embodiment 1, the reader / writer device 106 is fixed. That is, unlike the case of the reader / writer 206 of FIG. 12 described later, the reader / writer 106 of the first embodiment is assumed to be fixed at a predetermined position. In addition, when a tag exists in the readable range of the reader / writer device 106, it is assumed that the reader / writer device 106 is subject to a condition that the tag is read with an accuracy of 99.9% or more. This condition will be described later in the description of the operation.

(3) The filtering unit 103 performs a filtering process on the data acquired by the reader interface unit 104 from the reader / writer device 106, such as discarding the same data or extracting a difference from the previous time. . The data after execution is then passed to the application interface unit 101. In addition, the filtering unit 103 records, as a history, the read precision statistics information DB 105 with information such as a tag ID and read availability for each tag A to tag E or the like (an example of a read result) for each read. Add.

(4) The reader interface unit 104 issues a read command of the tags A to E to the reader / writer 106 and obtains information (reading result) as the response. In the "read command", it is also possible to identify and read a tag.

(5) The read precision statistics information DB 105 stores, as a read history, read precision statistics information indicating information such as readability of the reader / writer device 106 that each of the tags A to tags E has been read in the past. . The read precision statistics information DB 105 accumulates the read result as a history each time the reader / writer device 106 newly reads the tags A to E. Specifically, the read history is the ID, read availability, read time, etc. of each tag. These will be described later in the description of FIG. 7.

(6) In addition, in FIG. 1, the arrow 11-the arrow 14 of a solid line have shown the control data. Incidentally, the dashed arrows 21 to 24 indicate the read data. White empty arrows 31 to 33 represent statistical information data.

Next, the operation of the RFID tag read control device 100 will be described with reference to FIGS. 4 and 5. 4 is a flowchart illustrating the operation of the RFID tag read control device 100. FIG. 5 corresponds to FIG. 1 and shows the contents of signals exchanged in each component.

(1) The application interface unit 101 receives an "RFID tag read command" (an example of a read request) from the application program 107. This " RFID tag read command " includes a tag ID for identifying a tag (hereinafter sometimes referred to as a read target) for requesting reading. In response to receiving the "RFID tag read command", the application interface unit 101 issues a "read command" to the self-tuning unit 102 (S101). The "read command" includes a tag ID to be read.

(2) When the self-tuning unit 102 receives the "read command" from the application interface unit 101, the self-tuning unit 102 accesses the read precision statistics information DB 105 and confirms the existence of the requested tag ID (S102). ). When the requested tag ID exists, the self tuning unit 102 calculates and determines the number of readings from the past reading situation (S103). On the other hand, when there is no tag ID corresponding to the read precision statistics information DB 105, the self-tuning unit 102 sets a fixed number of times (S104). The determination of the number of readings is further described later. The self tuning unit 102 issues the tag ID corresponding to each reading target and the number of readings to the reader interface unit 104. In addition, the self tuning unit 102 notifies the filtering unit 103 of the determined number of designated times. The filtering unit 103 stores, as a history, the tag ID and the number of times of receiving the notification in the read precision statistics information DB 105.

(3) The reader interface unit 104 issues a " read command " of " specified read count " which is the number of reads determined or set by the self-tuning unit 102 to the reader / writer 106 (S105).

(4) The reader interface unit 104 receives a response to the "read command" from the reader / writer device 106 (S106), and sends the result of the response to the filtering unit 103. The "response" in this case is a read result in which the reader / writer device 106 reads a tag to be read.

(5) Upon reception of the response (read result) from the reader interface unit 104, the filtering unit 103 determines whether "the specified number of times has been reached" (S107). If it has not reached (NO in S107), the filtering unit 103 waits again for the read result from the reader interface unit 104. The reader interface unit 104 continues to return the result until the number of readings received from the self-tuning unit 102 is performed. When it is determined that the specified number of times has been reached (YES in S107), the filtering unit 103 aggregates the reading results thereto and determines whether the reading is successful (S108).

(6) When it is determined that there is no read success result in the read result (NO in S108), the filtering unit 103 notifies the application interface unit 101 of "no request tag" (S109).

(7) When it is determined that at least one time has been read (YES in S108), the filtering unit 103 adds the read result to the read precision statistical information DB 105 (S110). In addition, the filtering unit 103 returns "with a request tag" to the application interface unit 101 (S111).

(8) The application interface unit 101 returns the result of the "presence or absence of a tag" returned from the filtering unit 103 to the application program 107 (S112).

(9) The read operation is completed.

Next, the "determination of the number of readings" described in step 103 of FIG. 4 will be further described with reference to FIGS. 6 to 11. 6 is a flowchart illustrating the operation of the self tuning unit 102. An operation of the self tuning unit 102 will be described with reference to FIG. 6.

The method of counting the number of readings by the self tuning unit 102 (S103 in FIG. 4) varies depending on the system conditions. In the first embodiment, it is assumed that the reading accuracy when the reader / writer device 106 reads each tag is 99.9% or more.

First, FIG. 7 will be described. FIG. 7: is a figure which shows the example of "reading precision statistics information" (an example of reading history) which the reading precision statistics information DB105 stores. In the state shown in FIG. 1, in the state shown in FIG. 1, the five tags of the tag A to the tag E are within the readable range of the reader / writer 106, and the reader / writer device 106 each reads. The read result of reading the tag 100 times is included. Specifically, the "reading accuracy statistical information" includes the "reading time" at which the reader / writer device 106 reads the tag, the "tag ID" identified by the letters A to E, and the reader / writer device 106. The "number of reading trials" in which the tag is read and the "number of successful readings" in which the reading is successful among the number of reading trials are included. Regarding the number of readings, the "reading accuracy statistical information" is a result of the reader / writer 106 reading each of the tags A to tag E ten times at the time "15:26:30", and the time "15:26". : 35 "stores the result of repeating this ten times, such as the result of having read each of tag A-tag E ten times. Thereby, the result of having read 100 times with respect to each tag is obtained.

The operation of the self tuning unit 102 will be described with reference to FIG. 6.

(1) In S201, the self-tuning unit 102 inquires the read precision statistics information DB 105 of all the "read precision statistics information" of the tag ID of the tag that is "read target". In this example, it is assumed that all of the tags A to E are "read targets".

(2) In S202, the "self-tuning unit 102" counts "total number of readings" and "number of successful readings". 8 shows the counting result by the self tuning unit 102. "Total number of reads" is 100 times. This is because, as described above, the "reading precision statistical information" has data obtained by reading each tag 100 times.

(3) In S203, the self tuning unit 102 calculates "one read accuracy" (an example of success probability) of each tag that is "read target". "One time reading accuracy" is, for example,

"1 reading accuracy = number of successful readings / total number of readings"

Obtain as FIG. 8 shows "one read accuracy" obtained by the data obtained from the read accuracy statistical information DB 105. As shown in FIG. 8, the tag A is 100% and the tag B is 92%. to be.

(4) In S204, the self tuning unit 102 determines the number of readings of the tags A to E that are "read targets". Determination of the number of readings will be described in comparison with the prior art. Consider the case where five reads are performed on each of the tags A to E according to the prior art under the condition of "one read accuracy" shown in FIG. The total number of reads is 5 × 5 = 25 times because each of the five tags is read five times. The reading accuracy in the case of reading five times by the prior art is the same as the value of the column of "Reading precision of the prior art" in FIG. As shown in Fig. 9, the "reading accuracy of the prior art" of the tag A is 100%, the "reading accuracy of the prior art" of the tag B is 99.999% or more, and the "reading accuracy of the prior art" of the tag C is 96.875%. to be. It is a figure explaining the calculation method of the reading precision of FIG. Regarding the reading accuracy in the case of reading the tag five times, first, consider a case in which one specific tag, for example, tag C, is read. The one reading accuracy (probability) of the tag C is called P.

As shown in Fig. 10, when reading five times,

When reading at the first time, the precision (probability) P,

The accuracy at the second reading is (1-P) ¹ ㆍ P,

The accuracy at the third reading is (1-P) ² ㆍ P,

The accuracy at the fourth reading is (1-P) ³ ㆍ P,

The accuracy at the fifth reading is (1-P) ⁴ ㆍ P

Becomes

The reading accuracy (probability to be read) when tag C is read five times may be summed up.

In other words,

P + ^(1-P) 1 and P (1-P) ² and P + (1-P) ³ and P + (1-P) ⁴ and P

Becomes

In the above example, the read accuracy (probability) P (n) when n reads is

P (n) = 1- (1-P) ⁿ (Equation 1)

Becomes In tag C, P = 0.5 and n = 5. Substituting them in Equation 1,

Tag C reading accuracy P (5) when read five times

P _C (5) = 0.96875 (96.875%)

Becomes On the other hand, in the first embodiment, for example, any tag is not read every equal number of times, such as five times. The self-tuning unit 102 determines the number of readings for each tag so that the reading accuracy (reading probability) is 99.9% or more for all the tags A to E that are the reading targets. In this case, the number of readings of each tag determined by the self tuning unit 102 is as shown in the table of FIG. 11. This indicates that the tag with poor read accuracy is mainly read. "The present system reading precision" shown in FIG. 11 is demonstrated. As described in FIG. 10, the read accuracy P (n) when n reads for a tag having one read accuracy (probability) is P,

P (n) = 1- (1-P) ⁿ (Equation 1)

to be.

In Fig. 11, tag B is considered. As shown in Fig. 8, the " one read accuracy "

P = 0.92

to be. Further, the left side of Expression 1 is 0.9999.

The self tuning unit 102 finds the minimum n that satisfies Expression 1 from this condition. N is the number of readings to which the tag B should be read.

From the above conditions

n = 3

Becomes In that case, the reading accuracy will be 99.9488%. The same is true for other tags. According to the read accuracy of the present system shown in Fig. 11, the total number of reads is 18 times. The total number of reads is seven times smaller than that of 25 times using the conventional method of FIG. In addition, even in reading accuracy, 99.9% can be expected in all tags. In the conventional method, when reading five times, the reading accuracy of the tag C is 96.875%, which is lower than 99.9%.

As described in step 110 of FIG. 4, the filtering unit 103 accumulates the read result of the tag ID that has been successfully read, in addition to the read precision statistics information DB 105 as the read history. For this reason, as the number of readings increases, the reading accuracy of the tag can be improved. In addition, data that is too old may lower the precision. Therefore, when the total number of reads is more than a certain number of times, it is preferable to take an operation method such as deleting from old data. In addition, since a tag with no reading history is read out at a fixed number of times as described in step 104 of FIG. 4, it is possible to read the information of a tag to be read accurately and efficiently regardless of the presence or absence of the reading history.

In the RFID tag read control device 100 according to the first embodiment, the self-tuning unit 102 attaches the tag to the reader / writer device based on the read precision statistics information stored in the read precision statistics information DB 105. Read conditions for reading are determined. For this reason, the reading accuracy in the case where the reader / writer device 106 reads the tag can be improved. In addition, the read efficiency by the reader / writer can be improved.

The RFID tag read control device 100 according to the first embodiment obtains a read result in which the filtering unit 103 reads a tag from the reader / writer device 106, and uses the read result as a history to read the read precision statistical information DB ( 105). For this reason, the reliability of reading accuracy statistical information can be made high, and the reading accuracy of a tag can be made high.

The RFID tag read control device 100 according to the first embodiment acquires the read condition determined by the filtering unit 103 by the self-tuning unit 102 and the read result when the reader / writer device 106 reads the tag, These are stored in the read precision statistical information DB 105 as a history. For this reason, the reading accuracy of a tag can be improved. In addition, the read efficiency can be improved.

In the RFID tag read control device 100 according to the first embodiment, the read precision statistics information DB 105 stores the number of reads of the tag and the number of successful reads, and the filtering unit 103 reads the read precision statistics information DB 105. The number of readings by the reader / writer is determined based on the number of readings stored and the number of successful readings. For this reason, the tag can be read accurately and the total number of times of reading can be reduced.

The RFID tag read control device 100 according to the first embodiment uses the self-tuning unit 102 to determine the number of readings of the tag to be read from the ratio of the number of successful reads and the number of reads stored in the read precision statistics information DB 105. Decide For this reason, it is possible to precisely determine the number of reads with which the read is likely to succeed.

(Example 2)

Embodiment 2 is demonstrated using FIGS. 12-15. 12 shows the configuration of an RFID tag reading system 2000 according to the second embodiment. In the first embodiment, by using the history stored in the read accuracy statistical information DB 105, the number of readings of the reader / writer 106 is adjusted to increase the read accuracy when the tag is read. The reader / writer of the second embodiment is a "readable reader / writer". Then, the RFID tag reading control device performs control for moving the reader / writer device to an optimal position (reading position) for reading each tag, based on the past history. By the reader / writer device reading the tag at the optimum reading position, the reading accuracy can be increased. The same applies to the case where the "reader attached to the reader / writer" is moved in addition to the case where the reader / writer equipped with the antenna is moved. In the case of a "movable reader / writer", when the antenna portion and the portion other than the antenna portion of the reader / writer move (move) as a unit, and only the antenna portion of the reader / writer moves (moves) It includes both sides.

12 is a view illustrating the configuration of the RFID tag reading system 1000 according to the first embodiment, the reader / writer device 206 is movable along the rail 209. The rest of the configuration is the same as that of the RFID tag reading system 1000 of the first embodiment shown in FIG. In Fig. 12, solid arrows 211 to 214 indicate control data. Further, dotted arrows 221 to 224 represent read data. White empty arrows 231 to 233 indicate statistical information data.

The RFID tag read control device 200 is based on the “read accuracy statistics information” stored in the read accuracy statistics information DB 205, and the position and tag of the reader / writer device 206 with respect to the reader / writer device 206. Control the number of times of reading. 12 illustrates a case where the reader / writer device 206 moves along the straight rail 209. But this is an example. The reader / writer device 206 may move along a curved rail in addition to a straight line. In addition, the reader / writer device 206 may rotate to change the angle of its own posture, or may change to combine movement and rotation. In addition, the reader / writer device 206 may designate a three-dimensional position and move it to an arm or the like. It does not matter as long as it can be controlled by control information from the tag reading control device. As described above, the antenna portion of the reader / writer may be changed.

In Example 2 shown in FIG. 12, the self-tuning part 202 designates the coordinate of the rail 209 of the reader / writer 106 as control information (an example of a read condition). Thereby, the movable reader / writer device 206 can be moved to the predetermined position of the rail 209.

13 shows an example of "reading precision statistical information" stored in the reading precision statistical information DB 205. The read precision statistical information DB 205 changes the coordinates of the reader / writer device 206, and stores in advance the read result of reading each of the tags A to E. 7 of Example 1, FIG. 13 contains a "reading position" as a history.

The self-tuning unit 202 calculates the "position" on the rail 209 that is most suitable for reading, based on the history indicated by "reading precision statistical information" of the reading precision statistical information DB 205. As a calculation method, there is a method using a probability distribution and the like, but here, the average value is used for simplicity. 14 shows the result of reading the tag C by the reader / writer device 206. 15 is a graph of FIG. When the tag C read result is as shown in FIG. 14, FIG. 15, the average value of the position in the rail 209 is 5.5. This calculation method is as follows.

Average position = total / samples

= Σ (read position ＊ read success count) / Σ (read success count)

= 550/100

= 5.5

Becomes

For this reason, the self-tuning unit 102 moves the coordinates of the reader / writer device 206 to "5.5" to determine the read condition to be read, and outputs the read condition to the reader interface unit 204. The reader interface unit 204 moves the coordinates of the reader / writer 206 to "5.5" and issues a command to the reader / writer 206 to be read.

Here, although the example of the reader / writer apparatus 206 which moves on the straight rail 209 was provided, the reader / writer apparatus 206 is equipped with the other moving means, and the read precision statistics information DB 205 has the control information. Is accumulated as a plurality of parameters. In this way, an optimal combination of parameters can be obtained.

In addition, in order to further increase the read probability, the reader / writer device 206 may read a plurality of times at the coordinates (read position) determined by the self-tuning unit 202.

The self-tuning unit 102 may also perform control such as reading while moving in the vicinity of the coordinate (reference position) determined by the self-tuning unit 102.

For each reading of the tag performed in this way, the result is accumulated in the reading precision statistics information DB 205 as a history. As a result, even when the position of the tag is somewhat moved, the reader / writer 206 can read at the optimum position in accordance with the movement of the tag.

By the above, the tag reading by the reader / writer provided with the moving means can be efficiently performed.

The RFID tag read control apparatus 200 according to the second embodiment determines the read position of the movable reader / writer 206 based on the read precision statistics information stored in the read precision statistics information DB 205. This enables the tag to be read accurately.

In the RFID tag read control device 200 according to the second embodiment, the self-tuning unit 202 determines a plurality of read positions of the reader / writer based on the read precision statistics information stored in the read precision statistics information DB 205. do. Therefore, even when the position of the tag changes, the tag can be read in accordance with the change of the position.

In the RFID tag reading control device 200 according to the second embodiment, the self-tuning unit 202 determines the reading position and the number of readings of the tag based on the reading precision statistics information stored in the reading precision statistics information DB 205. do. This enables the tag to be read accurately.

(Example 3)

Next, Example 3 is demonstrated using FIGS. 16-18. 16 shows the configuration of an RFID tag reading system 3000 according to the third embodiment. In the first and second embodiments, the read control system in the case of one reader / writer has been described. The third embodiment is characterized in that the RFID tag reading system 3000 includes a plurality of reader / writer devices 306a to 306d. The rest of the configuration is the same as that of the RFID tag reading system 1000 of the first embodiment shown in FIG. In Fig. 16, arrows 311 to 314 of solid lines indicate control data. Further, dotted arrows 321 to 324 represent read data. White empty arrows 331 to 333 represent statistical information data.

In FIG. 16, each reader / writer device shall be equipped with the antenna (not shown) which communicates with a tag. In addition to the case where each of the plurality of reader / writer devices includes an antenna, the reader / writer device includes a plurality of antennas, and each of the plurality of antennas reads at least one of the plurality of tags A to E. It is also the same as having a plurality of reader / writer devices. Therefore, in the case of a plurality of reader / writer devices, in addition to the plurality of reader / writer devices each having an antenna, the plurality of antennas are provided as described above, and each of the plurality of antennas reads at least one tag. It is assumed to include both reader / writer devices.

When a plurality of reader / writer devices 306a to 306e are provided (including the case where the reader / writer device includes a plurality of antennas as described above), the read result in each reader / writer device is read out. Accumulate at 305. As the "read result", the number of the reader / writer device that can be read is recorded together with the number of reading successes. This makes it possible to select the reader / writer that is most suitable for reading with respect to the tag that is to be read.

17 is an example of "reading precision statistical information" stored in the reading precision statistical information DB 305. As shown in FIG. 17, the "reading precision statistics information" records the state of whether or not each tag and the reader / writer are read. When reading a tag, the self-tuning unit 302 searches the read precision statistics information DB 305 for "read precision statistics information" of the tag ID of the object to be read (for example, tag B). The self tuning unit 302 selects one of the reader / writer devices having the highest reading accuracy.

18 is a search result of tag B which the self-tuning unit 302 searches for and reads the read precision statistical information DB 305. In the case of the search result shown in FIG. 18, the self-tuning unit 302 determines the read condition under which the reader / writer 306b of NO2 should be selected as the device for reading the tag B. As shown in FIG. The reader interface unit 304 issues a read command to the selected reader / writer 306b. The reading result from the reader / writer device 306b is added as a history to the reading precision statistics information DB 305 via the filtering unit 303 from the reader interface unit 304.

In the example in which the above-described NO2 reader / writer 306b is selected, the reader / writer 306b is selected as the device having the highest read probability. However, the method of determining the read condition by the self tuning unit 302 is not limited to the above. When the self-tuning unit 302 determines that the read probability is not sufficient in one reader / writer, the self-tuning unit 302 can issue a command to read the same tag to the plurality of reader / writer devices. It demonstrates in the case of FIG. When the tag B is read using the reader / writer 306b of NO2 having the highest read probability, the read probability is 92%. At the same time, however, the reader / writer 306a of NO1 also reads the same tag B. FIG. In that case, the probability to be read

(1-0.08 * 0.1) * 100 = 99.2%

Up to.

In addition, when the read probability is sufficient, efficiency may be important. In that case, the self-tuning unit 102 determines the read condition in which each reader / writer reads different tags suitable for respective readings simultaneously, and controls the entire reader / writer. This can shorten the total read time until all the specified tags are read. For example, the self-tuning unit 302 reads the tag A by the reader / writer 306a, the reader / writer 306b reads the tag B, the reader / writer 306c reads the tag C, and the reader. The lighter device 306d determines the read condition for reading the tag D and the tag E. FIG.

As described above, tag reading by the plurality of reader / writer devices can be efficiently performed.

In the RFID tag read control device 300 according to the third embodiment, the self-tuning unit 302 reads a tag from a plurality of reader / writer devices based on the read precision statistics information stored in the read precision statistics information DB 305. The reader / writer is determined. For this reason, an optimal reader / writer for reading the tag to be read can be selected.

In the RFID tag read control device 300 according to the third embodiment, the filtering unit 303 receives the tag read result from the reader / writer device and stores it in the read precision statistics information DB 305 as a history. For this reason, the reliability of reading precision statistical information can be improved. In addition, the read accuracy of the tag can be increased.

In the RFID tag read control device 300 according to the third embodiment, the self-tuning unit 302 selects a plurality of reader / writer devices based on the read precision statistics information stored in the read precision statistics information DB 305, The plurality of selected reader / writer devices are read out as tags to be read. For this reason, the tag to be read can be read reliably.

The RFID tag read control device 300 according to the third embodiment includes a reader / writer for each tag to which the self-tuning unit 302 is to read, based on the read precision statistics information stored in the read precision statistics information DB 305. Select. For this reason, a tag can be read efficiently.

(Example 4)

Example 4 is demonstrated using FIG. 19, FIG. 19 shows the configuration of an RFID tag reading system 4000 according to the fourth embodiment. The fourth embodiment is an embodiment in which information indicating the presence status of each of a plurality of tags is obtained from a system that grasps the presence status of a plurality of tags, and the read condition is determined from the acquired presence status of the tags.

When the reader / writer device reads an RFID tag, the reading accuracy may change due to interference with other RFID tags in the vicinity. In particular, when RFID tags are in close proximity, it becomes difficult to read. For this reason, it is necessary to read intensively, for example, to increase the number of readings.

For example, when a plurality of RFID tags are used at a store of a rental DVD, a facility management site, or the like, the rental status of a DVD and the status of a facility are often recorded separately in a separate application program. In FIG. 19, the RFID tag reading system 4000 is characterized in that the self-tuning unit 402 is connected to the loan system 4001 with respect to the RFID tag reading system 1000 of the first embodiment. The rest of the configuration is the same as that of the RFID tag reading system 1000 of the first embodiment shown in FIG. In Fig. 19, solid arrows 411 to arrow 414 indicate control data. Further, dotted arrows 421 to arrow 424 represent read data. White empty arrows 431 to 433 represent statistical information data. The self tuning unit 402 has a function of cooperating with the inventory information DB 4002 managed by the application program of the loan system 4001. This association makes it possible to grasp the existence of surrounding tags.

20 shows "reading precision statistical information" stored in the reading precision statistical information DB 405. FIG. 20 shows "stock information" (an example of first existence status information) as a history in FIG. 7 showing "reading precision statistical information" of the first embodiment. When the self-tuning unit 402 determines the read condition of the tag to be read, the self-tuning unit 402 stores the latest stock information as the history in the read precision statistics information DB 405 from the stock information DB 4002 of the loan system 4001. To acquire. The acquired inventory information is stored as a history in the read precision statistics information DB 405 together with the read rate (the number of read trials and the number of successful reads).

After the predetermined amount of information is accumulated, the self-tuning unit 402, when there is a tag reading request from the application program 407, inventory the current inventory information (an example of the second existence status information) of the loan system. Obtained from information DB4002. Then, the self-tuning unit 402 reads the read availability status at the time of the loan pattern (first existence status information) as the history closest to the current stock information (second existence status information), and the reading precision statistical information DB 405 The number of readings is determined from.

The case of inventory will be described by way of example with reference to FIG. See tag A. Tag A has two types of "reading time" data. "2004/10/10 1/115: 36: 30" and "2004/10/10 1/115: 36: 35". Tag A has a "reading time" of "2004/10/1 15:36" even when "reading time" is "tag N inventory status (exists)" of "2004/10/1 15:36:30". The reading rate does not change even when " tag N is in the loan (does not exist) " In either case, the number of successful reads is 10 out of the number of reads performed 10 times.

However, it can be seen that tag B has a low read rate due to the presence of tag N. In other words, in the case where the "reading time" is "tag N is in loan" of "2004/10/10/1 15:36:35", the tag B has 10 reading success times out of 10 reading attempts. On the other hand, when "Tag N is in stock" of "2004/10/10 1/115: 36: 30", the number of successful readings is seven out of ten times of reading trials. Therefore, at the time of reading tag B, the number of readings is increased or decreased by the method of Example 1 according to the stock situation of tag N. FIG.

For example, in the following equation 1 described in Example 1,

Reading accuracy = 1- (1-P) ⁿ (Equation 1)

When tag N is present, the one-time reading precision P of tag B is obtained from the equation of S203 in FIG.

P = number of successful readings / total number of readings = 7/10 = 0.7

Becomes When the reading accuracy is 99.99% or more, n = 6 times in Equation 1.

Therefore, for the tag B, the self-tuning unit 402 determines the number of reads to six times when the tag N exists.

In this way, the read rate of the tag can be increased and the read efficiency can be increased.

The RFID tag read control device 400 according to the fourth embodiment reads the self-tuning unit 402 based on the read precision statistics information stored in the read precision statistics information DB 405 and the inventory information provided by the loan system. Determine the condition. For this reason, the reading accuracy of a tag can be improved.

The RFID tag read control device 400 according to the fourth embodiment uses the self-tuning unit 402 as a tag based on the read precision statistics information stored in the read precision statistics information DB 405 and the uplifting information provided by the loan system. The number of readings in case of reading is determined. For this reason, a tag can be read reliably.

(Example 5)

A fifth embodiment will be described with reference to FIGS. 21 and 22. The fifth embodiment is an embodiment in which the self tuning unit determines the transmission output of the reader / writer as a read condition. 21 shows a configuration of an RFID tag reading system 5000 according to the fifth embodiment. In the RFID tag reading system 5000, the distance between the reader / writer 507 and each tag of the tag group 508 is varied. In this case, the tag near the reader / writer 506 may be read with a smaller transmission output than the tag far away, while the tag far from the reader / writer 506 is the tag near. Compared to the larger transmission output.

The configuration of the system is similar to that of the RFID tag reading system 1000 of the first embodiment shown in FIG. In Fig. 21, solid arrows 511 to arrow 514 represent control data. Further, dotted arrows 521 to 524 represent read data. White empty arrows 531 to 533 represent statistical information data.

22 shows "reading precision statistical information" stored in the reading precision statistical information DB 505. "Reading accuracy statistical information" in FIG. 22 includes read rates (the number of reading trials and the number of successful readings) for each radio wave output (transmission output). In the fifth embodiment, the reader / writer 506 makes it possible to change the output in units of 0.1 watts. When the tag is read, the self tuning unit 502 inquires the read precision statistical information DB 505 of the read situation for each tag in accordance with the read request. Then, the output radio wave with the highest read rate is determined as the read condition, and a command is issued to read out from this output.

In the reading situation as shown in Fig. 22, when the reader / writer 506 is read the tag A, a sufficient reading rate cannot be obtained with an output of 0.1 watt. The success rate of 0.1 watts is 8/10. However, it can be seen that, if 0.2 watts, a read rate of 100% (10/10) can be ensured, and output of 0.3 watts or more is unnecessary. In this case, the self-tuning unit 502 determines the transmission output of the reader / writer 506 that reads the tag A at 0.2 watts.

In addition, even when the most suitable transmission output is selected, sufficient read rate may not be obtained. In such a case, the reading rate can be increased by increasing the number of readings in the manner of the first embodiment.

In addition, when there are several reader / writer devices, it is possible to select a reader / writer device that can be read with a small transmission output. Therefore, the tag can be read with high efficiency and low power.

In the RFID tag read control device 500 according to the fifth embodiment, the self-tuning unit 502 determines the transmission output of the reader / writer device based on the read precision statistics information stored in the read precision statistics information DB 505. . Thus, the reader / writer can be reliably read the tag.

As described above, the reader / writer device control device (RFID tag read control device) described in Embodiments 1 to 5 has the following functions.

(1) an input unit for receiving a tag operation request from an application program,

(2) a self-tuning unit for automatically determining a reading method having the highest reading rate under the conditions of the system by referring to a database;

(3) a filtering unit that leaves information on the read and unread tags and the situation at the time of reading the tag in the database when the tag is read,

(4) a database for holding readability information and a situation at the time of reading as a history;

(5) A command issuing unit for issuing a reader / writer device control command determined by the self-tuning unit to the reader / writer.

Hereinafter, the reader / writer device control device (RFID tag read control device) described in Embodiments 1 to 5 has the following functions.

(1) a mechanism for controlling the position of the reader / writer device,

(2) an input unit for receiving a tag operation request from an application,

(3) a self-tuning unit for automatically determining the position of the highest reading rate under the conditions of the system with reference to the database;

(4) a filtering unit for leaving in a database the information of the read tag and the unread tag and the position of the reader / writer device at the time of reading the tag,

(5) a database for holding readability information and the position of the reader / writer at the time of reading as a history;

(6) A command issuing unit for issuing a reader / writer device control command determined by the self-tuning unit to the reader / writer.

As described above, the reader / writer device control device (RFID tag read control device) described in Embodiments 1 to 5 has the following functions.

(1) a mechanism for simultaneously controlling a plurality of reader / writer devices,

(2) an input unit for receiving a tag operation request from an application,

(3) a self-tuning unit for automatically determining the reader / writer having the highest read rate under the system conditions by referring to the database;

(4) a filtering unit for leaving in a database the information of the read tag and the unread tag, and the identifier of the reader / writer device used for reading, when the tag is read;

(5) a database which holds, as a history, read availability information and an identifier of a reader / writer device used for reading;

(6) A command issuing unit for issuing a reader / writer device control command determined by the self-tuning unit to the reader / writer.

As described above, the reader / writer device control device (RFID tag read control device) described in Embodiments 1 to 5 has the following functions.

(1) a mechanism for retrieving data from a database of separate applications,

(2) an input unit for receiving a tag operation request from an application,

(3) a self-tuning unit for automatically determining a reading method having the highest reading rate under the conditions of the system by referring to a database;

(4) a filtering unit for leaving in a database the information of a tag which can be read, a tag which could not be read, and the presence information of a surrounding tag at the time of reading a tag,

(5) a database for holding readability information and presence information of neighboring tags at the time of reading as a history;

(6) A command issuing unit for issuing a reader / writer device control command determined by the self-tuning unit to the reader / writer.

As described above, the reader / writer device control device (RFID tag read control device) described in Embodiments 1 to 5 has the following functions.

(1) a mechanism for controlling the radio wave output of the reader / writer device,

(2) an input unit for receiving a tag operation request from an application,

(3) a self-tuning unit for automatically determining the radio wave output having the highest read rate under the conditions of the system with reference to the database;

(4) a filtering unit that leaves information on the read and unread tags and the radio wave output of the reader / writer at the time of reading the tag in the database;

(5) a database for holding readability information and the radio wave output of the reader / writer during reading as a history;

(6) A issuing unit for issuing a reader / writer device control command determined by the self-tuning unit to the reader / writer.

Claims (17)

A reading device control device for controlling a reading device that reads the information by communicating with a plurality of information storage devices that store predetermined information, A read request receiving unit which receives a read request requesting reading of at least one of the plurality of information storage devices; A reading history storage section for storing reading history in which the reading device has read each of the plurality of information storage devices in the past; The read condition determined based on the read history stored by the read history storage unit to determine a read condition for reading the read object indicating the information storage device related to the read request received by the read request receiving unit into the read device; A read condition determiner which reads the read target to the read device in accordance with a condition Readout device control apparatus comprising a. The method of claim 1, The reading device control device, The reading device receives a reading result of reading the reading object according to the reading condition from the reading device, and has a history control section for storing the received reading result as the reading history in the reading history storage unit. A reader device control device. The method of claim 2, The reading condition determining unit notifies the history control unit of the determined reading condition; And the history control unit stores the read condition notified from the read condition determiner as the read history in the read history storage unit. The method of claim 1, The read history stored in the read history storage section includes a read number of times that the read device reads each of the plurality of information storage devices and a success number of successful reads among the read times, And the reading condition determining unit determines, as the reading condition, the number of readings when the reading device reads the reading target. The method of claim 4, wherein When the read condition determining unit determines the read count as the read condition, the read condition determiner calculates a success probability that the read succeeds from the read count and the success count included in the read history, and based on the calculated success probability. The reading device control device, characterized in that the number of readings is determined. The method of claim 1, The reading device is movable and can be controlled in position, The read history stored in the read history storage section includes a read position of the read device when the read device reads each of the plurality of information storage devices, The reading condition determining unit determines, as the reading condition, a reading position of the reading device when the reading device reads the reading target. Readout device control device characterized in that. The method of claim 6, And the reading condition determining unit determines, as the reading condition, a plurality of reading positions of the reading device when the reading device reads the reading target. The method of claim 6, The read history stored in the read history storage section further includes the number of reads at the read position and the number of successes of successful reads among the read counts, The reading condition determining unit is configured to read, as the reading condition, the reading position of the reading device when the reading device reads the reading object, and the number of readings when the reading device reads the reading object at the reading position. And a reading device control device. The method of claim 1, The read history stored in the read history storage unit is first existence situation information indicating a presence situation of each of the plurality of information storage devices when the reading device reads each of the plurality of information storage devices. Including, The reading condition determination unit is a second existence indicating the presence situation of each of the plurality of information storage devices from the presence situation determination system which grasps the existence situation of each of the plurality of information storage devices when the reading condition is determined. Acquiring the situation information and determining the reading condition based on the first existence situation information included in the reading history and the second existence situation information acquired from the existence situation identifying system. Readout device control device characterized in that. The method of claim 9, The read history stored in the read history storage section includes a read number of times that the read device reads each of the plurality of information storage devices and a success number of successful reads among the read times, The reading condition determining unit includes the second existence status information acquired from the presence status determining system, the first existence situation included in the reading history, the number of readings included in the reading history, and the reading history. Determining the number of readings when the reading device reads the information storage device as the reading condition based on the number of successes to be made. Readout device control device characterized in that. The method of claim 1, The read history stored in the read history storage section includes a transmission output of the read device when the read device reads each of the plurality of information storage devices, The reading condition determining unit determines, as the reading condition, the transmission output of the reading device when the reading device reads the reading target. Readout device control device characterized in that. A reading device control device that controls each of a plurality of reading devices that read the information by communicating with a plurality of information storage devices that store predetermined information. A read request receiving unit which receives a read request requesting reading of at least one of the plurality of information storage devices; A read history storage section for storing a read history in which each of the plurality of read devices read the plurality of information storage devices in the past; Determine at least one reading device for reading a reading object representing the information storage device related to the reading request received by the reading request receiving section from among the plurality of reading devices based on the reading history stored in the reading history storage section; And a read condition determination unit that reads the read target to the determined read device. Readout device control apparatus comprising a. The method of claim 12, The reading device control device, The reading apparatus determined by the reading condition determining unit to receive a reading result of reading the reading object from the reading apparatus, and having a history control unit storing the received reading result as the reading history in the reading history storage unit. Characterized Reader control device. The method of claim 12, The reading condition determining unit determines a plurality of reading devices for reading the reading object from among the plurality of reading devices, and reads the reading object to the determined plurality of reading devices. The method of claim 12, The read request receiving unit receives a read request for requesting reading of two or more information storage devices as the read target, The reading condition determining unit determines at least one of the plurality of reading devices for each reading object. Readout device control device characterized in that. A reading device control method for controlling a reading device that reads the information from a plurality of information storage devices storing predetermined information, A reading history in which the reading device read each of the plurality of information storage devices in the past, Receive a read request requesting reading of at least one of the plurality of information storage devices, A reading condition for reading the reading object indicating the information storage device related to the received read request to the reading device is determined based on the reading history, and the reading object is read into the reading device according to the determined reading condition. Letting Readout device control method characterized in that. A control program for controlling the reading device to a reading device control device that controls the reading device that reads the information from a plurality of information storage devices storing predetermined information, A process of storing a reading history in which the reading device reads each of the plurality of information storage devices in the past; A process of receiving a read request requesting reading of at least one of the plurality of information storage devices; A reading condition for reading the reading object indicating the information storage device related to the received read request to the reading device is determined based on the reading history, and the reading object is read into the reading device according to the determined reading condition. Letting treatment And the reading apparatus control device.

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