JP2016146093A - Identification system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To accurately recognize identification information having many digits including numbers, characters and symbols without increasing an identification body, when the identification body can be identified by identification information according to a resonant frequency of an antenna.SOLUTION: An identification system includes: an electromagnetic radiation part 42 configured to sequentially emit electromagnetic waves of a plurality of frequencies to each of a plurality of information carrying areas included in an identification body; a frequency detection part 43 configured to sequentially detect of resonant frequencies of an antenna according to reflection waves from the antenna to the electromagnetic waves; an individual ID recognition part 45 configured to recognize pieces of first identification information respectively associated with the detected resonant frequencies at an ID database 44; and an ID recognition part 46 configured to recognize second identification information by aligning the recognized pieces of first identification information according to an order that the resonant frequencies associated with the pieces of first identification information are detected at the frequency detection part 43.SELECTED DRAWING: Figure 6

Description

  The present invention relates to an identification system for identifying an identification object using a resonance frequency of an antenna.

  Conventionally, an OCR (Optical Character Reader) technique for reading identification information such as a postal code, an address, and a name of a postal item by image recognition has been used, and is disclosed in Patent Document 1, for example. By using such an image reading technique, it is possible to increase the speed and efficiency of the identification information reading process. However, in such an image reading technique, the identification information cannot be read when the surface on which the identification information is displayed is opposite to the reading surface, such as when the mail piece is turned over. Further, even when the identification information is hidden by a shield such as paper, the identification information cannot be read. Furthermore, depending on the print quality of the identification information, there is a possibility that the reading rate may be lowered or misreading may occur for characters that are difficult to distinguish such as “0” and “6”, “1” and “7”.

  In addition, for a delivery item, an ID for identifying the delivery item is displayed on the delivery slip as a barcode, and this is read using infrared rays to manage the delivery status and history of the delivery item. However, in the method of reading the ID using the barcode as described above, the barcode is optically read in the same manner as described above. Therefore, when the barcode is displayed on the surface not irradiated with infrared rays, the ID is read. I can't.

  Incidentally, in recent years, RFID technology for reading IDs in a non-contact state using electromagnetic waves has become widespread, and has begun to be introduced into the physical distribution field. In the RFID technology, an IC chip in which an ID is stored so as to be readable by electromagnetic waves is used, and the ID is read from the IC chip in a non-contact manner. Therefore, by applying RFID technology using such an IC chip to a mail piece or a delivery slip, it is possible to avoid the situation where the ID cannot be read due to the orientation of the reading surface or the shielding object as described above. Can do.

The identification body using such RFID technology is not limited to the one using an IC chip as described above, and has a plurality of antennas having different resonance frequencies, and a combination of a plurality of antennas without using an IC chip. It is also considered that the ID can be recognized. For example, the resonant frequency is detected for each antenna by changing the shape of the dielectric elements and capacitor elements that make up multiple antennas, or by changing the shape and orientation of the multiple antennas. Patent Document 2 discloses a technique for expressing an ID based on whether or not it is performed, that is, presence or absence of a plurality of antennas. If this technology is used, if the number of antennas is N, two information of “1” and “0” can be given depending on the presence / absence of one antenna, and there is no case where all antennas are not present. Thus, (2 ^N −1) IDs can be expressed in a recognizable manner. Further, by using no IC chip, it is possible to avoid an increase in cost due to an expensive IC chip.

JP 10-76732 A Japanese Patent Publication No. 7-80386

As described above, in the case where the ID is expressed by the presence / absence of a plurality of antennas having different resonance frequencies, when the number of antennas is N, only (2 ^N −1) IDs can be expressed. In general, an ID displayed on a delivery slip as described above is expressed by a number having a large number of digits, such as 12 digits, for example. As a result, the delivery slip becomes large. However, since the delivery slip is used by being affixed to a delivery item, the size of the delivery slip is limited.

  Therefore, for each digit constituting the ID, an antenna having a resonance frequency corresponding to the digit of the digit is formed, and by detecting the resonance frequency for each digit, an ID consisting of a number having a large number of digits. It is conceivable that the configuration can be recognized.

  However, in such a configuration, the resonance frequencies are not necessarily different among a plurality of digits, and depending on the ID, the resonance frequency may be the same because the numbers are the same in the plurality of digits. In that case, even if the resonance frequency is detected, there is a problem that it is impossible to recognize which digit the resonance frequency is, and accordingly, the ID cannot be accurately recognized. For example, an ID “1920045” is represented by arranging a plurality of antennas having resonance frequencies corresponding to “1”, “9”, “2”, “0”, “0”, “4”, “5”. In this case, since the order of “1”, “9”, “2”, “0”, “0”, “4”, “5” cannot be recognized, the ID is recognized as “1925400”. There is a risk that it may be mistaken or a duplicated number may be missed and recognized as “192045”.

  The present invention has been made in view of the problems of the prior art as described above, and is a number having a large number of digits in the identification object that can be identified by identification information corresponding to the resonance frequency of the antenna. An object of the present invention is to provide an identification system capable of accurately recognizing identification information including letters, characters, and symbols without enlarging the identification body.

In order to achieve the above object, the present invention provides:
An identification body having a plurality of information carrying areas to which first identification information that can be recognized by the resonance frequency of the antenna is formed is provided to each of the plurality of information carrying areas of the identification body. An identification system for identifying using second identification information formed by combining the first identification information,
A database associating the resonant frequency of the antenna with the first identification information;
Electromagnetic wave radiating means for sequentially radiating electromagnetic waves having a plurality of frequencies including the resonance frequency to each of a plurality of information-carrying regions included in one identifier;
For each of the plurality of information-carrying regions, frequency detection means for sequentially detecting a resonance frequency of the antenna by a reflected wave from the antenna with respect to the radiated electromagnetic wave;
First recognition means for recognizing first identification information associated with the detected resonance frequency in the database;
A second for recognizing the second identification information by arranging the recognized first identification information in accordance with the order in which the resonance frequency corresponding to the first identification information is detected by the frequency detection means; Recognizing means.

  In the present invention configured as described above, one discriminating body has electromagnetic waves having a plurality of frequencies including the resonance frequencies of the antennas formed in the plurality of information carrying regions of the discriminating body in the electromagnetic wave radiation means. The information is sequentially emitted to each of the plurality of information carrying areas, and the frequency detection means sequentially detects the resonance frequency of each of the plurality of information carrying areas by the reflected wave from the antenna with respect to the radiated electromagnetic waves. . Then, the first recognition means recognizes the first identification information associated with the detected resonance frequency in the database, and then the second recognition means recognizes the first identification information recognized. The second identification information is recognized by arranging the resonance frequencies corresponding to the first identification information in the order in which the frequency detection means detects them. Thereby, the arrangement order of the first identification information constituting the second identification information for identifying the identification body can also be identified, and the first information assigned to each of the plurality of information carrying areas of the identification body. The second identification information obtained by combining the identification information can be accurately recognized, and the identification object can be correctly identified by the second identification information.

  In addition, the identifier has a region having a reference resonance frequency, and one of the plurality of information carrying regions at the head or the tail in the direction in which the electromagnetic wave emitting means should sequentially emit the electromagnetic waves to the plurality of information carrying regions. And the second recognition means sets the first identification information arranged side by side with the side where the reference resonance frequency is detected by the frequency detection means as the head or tail. The direction in which the electromagnetic wave radiation means actually radiates the electromagnetic waves sequentially to the plurality of information carrying regions is opposite to the direction in which the electromagnetic waves should be radiated sequentially to the plurality of information carrying regions. The second identification information can be accurately recognized even in the case of the direction, and the identification object can be accurately identified by the second identification information.

  According to the present invention, an electromagnetic wave having a plurality of frequencies is sequentially emitted to each of a plurality of information carrying regions of the identification body, and the resonance frequency of the antenna is sequentially detected by a reflected wave from the antenna with respect to the electromagnetic wave. And recognizing the first identification information given to the plurality of information carrying areas, and then recognizing the recognized first identification information according to the order in which the resonance frequency corresponding to the first identification information is detected. The second identification information is recognized by recognizing the second identification information by arranging the first identification information provided in each of the plurality of information carrying areas of the identification body. Since the body is identified, the arrangement order of the first identification information constituting the second identification information can also be identified, whereby the identification body is identified by the identification information corresponding to the resonance frequency of the antenna. In what is another possible, numbers and letters large number of digits, the identification information consisting of symbols, can be accurately recognized without increasing the identifying object.

  In addition, the identifier has a region having a reference resonance frequency, and one of the plurality of information carrying regions at the head or the tail in the direction in which the electromagnetic wave emitting means should sequentially emit the electromagnetic waves to the plurality of information carrying regions. And the second recognition means sets the first identification information arranged side by side with the side where the reference resonance frequency is detected by the frequency detection means as the head or tail. The direction in which the electromagnetic wave radiation means actually radiates the electromagnetic waves sequentially to the plurality of information carrying regions is the direction in which the electromagnetic waves are to be radiated sequentially to the plurality of information carrying regions. Even in the reverse direction, the second identification information can be accurately recognized, and the identification object can be accurately identified by the second identification information.

It is a figure which shows an example of the identification body identified with the identification system of this invention, (a) is a figure which shows the whole structure, (b) is a figure which shows the structure of the number display area shown to (a), (C) is AA 'sectional drawing shown to (b). It is a figure which shows the frequency characteristic of the figure antenna in the number display area of the ID tag shown in FIG. It is a figure which shows the frequency characteristic of the figure antenna in the number display area of the ID tag shown in FIG. It is a figure which shows the example which varied the resonance frequency of the figure antenna in the number assignment | providing area | region about the ID tag shown in FIG. It is a figure which shows an example of the delivery slip to which the identification body which has the structure similar to what was shown in FIG. 1 is applied, (a) is a figure which shows the whole structure, (b) is the inquiry number shown in (a). It is a figure which shows the detailed structure of a display column. It is a figure which shows one Embodiment of the identification system of this invention. FIG. 7 is a diagram for explaining a method of recognizing an inquiry number displayed in an inquiry number display field of a delivery slip shown in FIG. 5 in the identification system shown in FIG. The figure which shows the state of the delivery slip at the time, (b)-(e) is a figure which shows the state of the detection via the antenna of the electromagnetic wave radiation | emission via an antenna, and the reflected wave from a figure antenna. FIG. 7 is a diagram showing frequency characteristics when the antenna shown in FIG. 6 is not directly facing the figure antenna, and (a) is a diagram showing frequency characteristics when the figure antenna shows the number “1”; ) Is a diagram showing the frequency characteristics when the figure antenna indicates the numeral “2”. It is a figure which shows the other example of the inquiry number display column of the delivery slip shown in FIG.

  Embodiments of the present invention will be described below with reference to the drawings.

  FIG. 1 is a diagram showing an example of an identification object identified by the identification system of the present invention, where (a) is a diagram showing the overall configuration, and (b) is an illustration of the number display area 11a shown in (a). The figure which shows a structure, (c) is AA 'sectional drawing shown to (b).

  As shown in FIG. 1, the identification body according to this example is an ID tag 1 configured by providing number display areas 11a to 11j serving as information carrying areas on a base substrate 10 made of paper, resin, or the like.

  In each of the number display areas 11a to 11j, the conductive portions 21a to 21j in which the conductors 24 are stacked in a solid shape on the base substrate 10, and the conductors 24 are not stacked on the base substrate 10. Figure antennas 20a to 20j are formed which are made of conductive portions 22a to 22j and have substantially the same outer shape.

  Each of the non-conductive portions 22a to 22j is configured by hollowing out the conductive portions 21a to 21j in the number display areas 11a to 11j into numbers having the identification information assigned to the number display areas 11a to 11j, respectively. Has been. Thereby, the non-conductive portion 22a has the shape of the numeral “1”, and the figure antenna 20a in the number display area 11a indicates “1”. Further, the non-conductive portion 22b has the shape of the numeral “2”, and the figure antenna 20b in the number display area 11b indicates “2”. Further, the non-conductive portion 22c has the shape of the numeral “3”, and the figure antenna 20c in the number display area 11c indicates “3”. Further, the non-conductive portion 22d has a numeral “4” shape, and the figure antenna 20d in the number display area 11d indicates “4”. Further, the non-conductive portion 22e has a numeral “5” shape, and the figure antenna 20e in the number display area 11e indicates “5”. Further, the non-conductive portion 22f has a numeral “6” shape, and the figure antenna 20f in the number display area 11f indicates “6”. Further, the non-conductive portion 22g has a numeral “7” shape, and the figure antenna 20g in the number display area 11g indicates “7”. In addition, the non-conductive portion 22h has a numeral “8” shape, and the figure antenna 20h in the number display area 11h indicates “8”. Further, the non-conductive portion 22i has the shape of the numeral “9”, and the figure antenna 20i in the number display area 11i indicates “9”. Further, the non-conductive portion 22j has a numeral “0” shape, and the figure antenna 20j in the number display area 11j indicates “0”. As a result, the identification information “1”, “2”, “3”, “4”, “5”, “6”, “7”, “8”, “9” assigned to the number display areas 11a to 11j, respectively. “,” “0” is visible. As shown in FIG. 1B, the non-conductive portion 22a is formed by cutting out the end portion 23 of the conductive portion 21a into the shape of the number “1”. Regarding the other non-conductive portions 22b to 22j Similarly, the shape of the identification information given to the number display areas 11b to 11j is cut out from the end portions of the conductive portions 21b to 21j. In addition, in this form, although the bottom part of the number which shows the identification information provided to the number display areas 11b-11j is in contact with the edge part of electroconductive parts 21a-21j, among non-conductive parts 22a-22j, it is conductive. The part which touches the edge part of the parts 21a-21j is not restricted to the bottom part of the number which shows the identification information provided to the number display areas 11b-11j. Moreover, the part which contact | connects the edge part of the electroconductive parts 21a-21j among the nonelectroconductive parts 22a-22j is not limited to one place, Two places etc. may be sufficient as a bottom part and a right side part, or a left side part.

  As described above, in the number display areas 11a to 11j, the conductive portions 21a to 21j are cut out from the end portions to form the non-conductive portions 22a to 22j. The antennas 20a to 20j have a shape that is partially open. As a result, the resonance frequencies of the figure antennas 20a to 20j in the number display areas 11a to 11j correspond to the shapes of the conductive portions 21a to 21j.

  Hereinafter, the resonance frequency of the figure antenna in the number display areas 11a to 11j will be described.

  For the ID tag 1 shown in FIG. 1, the resonance frequencies of the figure antennas 20a to 20j in the number display areas 11a to 11j were measured. In this case, FR4 (Flame Retardant Type 4) having a thickness of 1.6 mm is used as the base substrate 10, and the outer shapes of the figure antennas 20 a to 20 j are 6.5 mm × 8.5 mm, and the conductor 24 is 18 μm. What consists of copper foil of thickness was used. A patch antenna made of copper foil having a shape of 12 mm × 12 mm and a thickness of 18 μm was used as an antenna for transmitting / receiving electromagnetic waves to / from the ID tag 1. Under these conditions, the reflection coefficients of the figure antennas 20a to 20j were measured.

  2 is a diagram showing the frequency characteristics of the figure antennas 20a to 20j in the number display areas 11a to 11j of the ID tag 1 shown in FIG. 1, and (a) shows the frequency characteristics of the figure antennas 20a, 20i, and 20j. FIG. 4B is a diagram illustrating the frequency characteristics of the figure antennas 20b to 20d, and FIG. 5C is a diagram illustrating the frequency characteristics of the figure antennas 20e to 20h. The reason why the frequency characteristics of the figure antennas 20a to 20j in the number display areas 11a to 11j are divided into three diagrams is to easily show the difference between the frequency characteristics.

  When the figure antennas 20e to 20h are not obscured by the patch antenna, only one resonance point (hereinafter referred to as the first resonance point) is detected in the vicinity of 6.0 GHz, but the figure antenna in the number display area 11i is detected. When the patch antenna was brought closer to about 5 mm at 20i, a second resonance point (hereinafter referred to as a second resonance point) was detected in the vicinity of 4.6 GHz as shown by the solid line in FIG. Further, when the patch antenna was brought close to about 5 mm to the figure antenna 20j in the number display area 11j, the second resonance point was detected in the vicinity of 5.4 GHz as shown by the broken line in FIG. Further, when the patch antenna was brought close to about 5 mm to the figure antenna 20a in the number display area 11a, the second resonance point was detected in the vicinity of 5.2 GHz as shown by the alternate long and short dash line in FIG. Further, when the patch antenna was brought close to about 5 mm to the figure antenna 20b in the number display area 11b, a second resonance point was detected in the vicinity of 4.8 GHz as shown by the solid line in FIG. Further, when the patch antenna was brought close to about 5 mm to the figure antenna 20c in the number display area 11c, the second resonance point was detected in the vicinity of 4.9 GHz as shown by the broken line in FIG. Further, when the patch antenna was brought close to about 5 mm to the figure antenna 20d in the number display area 11d, the second resonance point was detected in the vicinity of 5.4 GHz, as indicated by the alternate long and short dash line in FIG. Further, when the patch antenna was brought close to about 5 mm to the figure antenna 20e in the number display area 11e, the second resonance point was detected in the vicinity of 4.5 GHz as shown by the solid line in FIG. Further, when the patch antenna was brought close to about 5 mm to the figure antenna 20f in the number display area 11f, the second resonance point was detected in the vicinity of 5.6 GHz as shown by the broken line in FIG. In addition, when the patch antenna was brought close to about 5 mm to the figure antenna 20g in the number display area 11g, the second resonance point was detected in the vicinity of 4.6 GHz as shown by the one-dot chain line in FIG. Further, when the patch antenna was brought close to about 5 mm to the figure antenna 20h in the number display area 11h, the second resonance point was detected in the vicinity of 5.4 GHz as shown by the two-dot chain line in FIG.

  Thus, the resonance frequencies of the figure antennas 20e to 20h in the number display areas 11a to 11j are set for the number display areas 11a to 11j in accordance with the shapes of the conductive portions 21a to 21j.

  However, the second resonance points of the figure antennas 20g and 20i in the number display areas 11g and 11i are substantially the same. This is because the non-conductive portion 22g in the number display area 11g has the shape of the number "7", and the non-conductive portion 22i in the number display area 11i has the shape of the number "9". Is due to being. The second resonance points of the figure antennas 20d, 20h, and 20j in the number display areas 11d, 11h, and 11j are almost the same. This is because the non-conductive portion 22d in the number display area 11d has the shape of the number “4”, the non-conductive portion 22h in the number display area 11h has the shape of the number “8”, and the non-conductive portion in the number display area 11j. This is because the portion 22j has the shape of the number “0” and at least the shapes of the non-conductive portions 22h and 22j are similar. Therefore, the ID tag 1 shown in FIG. 1 has a number display area that cannot be distinguished from each other only by the resonance frequency.

  Therefore, the resonance frequency was measured in the same manner as described above by changing the height of the number according to the shape of the non-conductive portion in the number display areas that cannot be distinguished from each other. In the following, the resonance frequencies measured for the figure antenna 20g and the figure antenna 2011i whose resonance frequencies are substantially the same in the measurement results described above are shown.

  FIG. 3 is a diagram showing the frequency characteristics of the figure antennas 20g and 20i in the number display areas 11g and 11i of the ID tag 1 shown in FIG. 1, in which the numerical heights of the non-conductive portions 22g and 22i are changed. It is.

  When the heights of the numbers “7” and “9” due to the shapes of the non-conductive portions 22g and 22i are 6.0 mm, respectively, if the patch antenna is brought close to about 5 mm to the figure antenna 20g in the number display area 11g, As shown by the solid line in FIG. 3 (a), the second resonance point is detected in the vicinity of 4.6 GHz, and even if the patch antenna is brought close to about 5 mm to the figure antenna 20i in the number display area 11i, FIG. ), The second resonance point was detected in the vicinity of 4.6 GHz. The first resonance point was 6.0 GHz for both the figure antenna 20g in the number display area 11g and the figure antenna 20i in the number display area 11i.

  When the heights of the numbers “7” and “9” due to the shapes of the non-conductive portions 22g and 22i are 4.5 mm, respectively, the patch antenna is brought closer to about 5 mm to the figure antenna 20g in the number display area 11g. As shown by the solid line in FIG. 3B, the second resonance point is detected in the vicinity of 5.8 GHz, and even if the patch antenna is brought close to about 5 mm to the figure antenna 20i in the number display area 11i, FIG. As indicated by the broken line in (b), a second resonance point was detected in the vicinity of 5.8 GHz. The first resonance point was 6.2 GHz for both the figure antenna 20g in the number display area 11g and the figure antenna 20i in the number display area 11i.

  When the heights of the numbers “7” and “9” due to the shapes of the non-conductive portions 22g and 22i are 6.7 mm, respectively, the patch antenna is brought close to about 5 mm to the figure antenna 20g in the number display area 11g. As shown by the solid line in FIG. 3C, the second resonance point is detected in the vicinity of 4.3 GHz, and even if the patch antenna is brought close to about 5 mm to the figure antenna 20i in the number display area 11i, FIG. As indicated by the broken line in (c), the second resonance point was detected in the vicinity of 4.3 GHz. The first resonance point was 6.0 GHz for both the figure antenna 20g in the number display area 11g and the figure antenna 20i in the number display area 11i.

  In this way, in the number display area where the resonance frequency is almost the same, even if the height of the number due to the shape of the non-conductive part is changed, the resonance frequency of the figure antenna also changes in the same way, and is distinguished by the resonance frequency I can't do it. Therefore, in the number display areas where the resonance frequencies are almost the same, the figure antennas have different resonance frequencies by changing the heights of the numbers due to the shape of the non-conducting parts. So that they can be distinguished.

  FIG. 4 is a diagram showing an example in which the resonance frequencies of the figure antennas 20a to 20j in the numbering areas 11a to 11j are different from each other for the ID tag 1 shown in FIG.

  As shown in FIG. 4, the numbers “1”, “6”, and “8” in the shape of the non-conductive portions 22a, 22f, and 22h in the number display areas 11a, 11f, and 11h are set to 6.0 mm. The heights of the numbers “2”, “3”, “5”, “7”, “0” depending on the shape of the non-conductive portions 22b, 22c, 22e, 22g, 22j in the areas 11b, 11c, 11e, 11g, 11j. The height of the numbers “4” and “9” of the non-conductive portions 22d and 22i in the number display areas 11d and 11i was 6.7 mm.

  Then, as described above, the resonance of the figure antennas 20g and 20i in the number display areas 11g and 11i, in which the second resonance points are substantially the same when the heights of the numbers due to the shape of the non-conductive portion are the same, The frequencies are different from each other, and similarly, the resonance frequencies of the figure antennas 20d, 20h, and 20j in the number display areas 11d, 11h, and 11j are different from each other.

  As described above, in the ID tag 1 shown in FIG. 1, different resonance frequencies are set for the respective figure antennas 20a to 20j in the number display areas 11a to 11j depending on the shapes of the non-conductive portions 22a to 22j of the figure antennas 20a to 20j. As a result, the resonance frequencies of the figure antennas 20a to 20j in the number display areas 11a to 11j are represented by numbers "1", "2", "3", "4", "5" according to the shapes of the non-conductive portions 22a to 22j. , “6”, “7”, “8”, “9”, “0”. Thereby, the numbers according to the shapes of the non-conductive portions 22a to 22j can be recognized by the resonance frequencies of the figure antennas 20a to 20j in the number display areas 11a to 11j. Further, the resonance frequencies of the figure antennas 20a to 20j are different from those of an antenna including only a conductive portion without being given a numeral.

  Thereby, when the reader which reads the number given to number display areas 11a-11j and the field in which number display areas 11a-11j of ID tag 1 were provided are not facing, number display areas 11a-11j Even when a shield such as paper is present on the top, the numbers assigned to the number display areas 11a to 11j can be recognized. In addition, as described above, the numbers given to the number display areas 11a to 11j can be recognized using electromagnetic waves, but even when the recognition by electromagnetic waves fails, the numbers are identified by the shapes of the non-conductive portions 22a to 22j. Information can be accurately recognized visually.

  In this example, by changing the height depending on the shape of the non-conductive portion, the resonance frequencies of the figure antennas that are the same when the numbers in the number display area are the same are different from each other. However, the resonance frequency can be made different by changing the size, font, inclination, number of areas in contact with the edge of the number display area, and the outer shape of the conductive part. Conceivable.

  Below, the specific example to which the ID tag 1 mentioned above is applied and the identification system of this invention using the same are demonstrated.

  FIG. 5 is a diagram showing an example of a delivery slip to which an identifier having a configuration similar to that shown in FIG. 1 is applied. (A) is a diagram showing the overall configuration, and (b) is a diagram showing (a). It is a figure which shows the detailed structure of the shown inquiry number display column.

  As shown in FIG. 5A, the delivery slip 30 in this example includes a delivery destination information display field 31 in which the address, name, etc. of the delivery destination of the delivery to which the delivery slip 30 is attached are displayed; A delivery source information display field 32 for displaying the address and name of the delivery source of the delivery, a product name display field 33 for displaying the name of the delivery, and a second identification for managing the delivery status of the delivery An inquiry number display field 34 in which an inquiry number serving as information is displayed is provided.

  As shown in FIG. 5 (b), the inquiry number display field 34 is provided with number display areas 111a to 111l as in the ID tag 1 shown in FIG. 1, and each of the number display areas 111a to 111l The figure antennas 120a to 120j including the conductive parts 121a to 121l and the non-conductive parts 122a to 122l constituting the figure antenna are formed.

  Each of the non-conductive portions 122a to 122l has a numerical shape serving as first identification information displayed in each of the number display areas 111a to 111l. Specifically, since the inquiry number displayed in the inquiry number display field 34 is “2313-4945-7806”, the non-conductive portion 122a changes the shape of the number “2” displayed in the number display area 111a. The figure antenna 120a indicates “2”. The non-conductive portion 122b has the shape of the number “3” displayed in the number display area 111b, and the figure antenna 120b indicates “3”. Further, the non-conductive portion 122c has the shape of the number “1” displayed in the number display area 111c, and the figure antenna 120c indicates “1”. The non-conductive portion 122d has the shape of the number “3” displayed in the number display area 111d, and the figure antenna 120d indicates “3”. The non-conductive portion 122e has the shape of the number “4” displayed in the number display area 111e, and the figure antenna 120e indicates “4”. The non-conductive portion 122f has the shape of the number “9” displayed in the number display area 111f, and the figure antenna 120f indicates “9”. The non-conductive portion 122g has the shape of the number “4” displayed in the number display area 111g, and the figure antenna 120g indicates “4”. The non-conductive portion 122h has the shape of the number “5” displayed in the number display area 111h, and the figure antenna 120h indicates “5”. The non-conductive portion 122i has the shape of the number “7” displayed in the number display area 111i, and the figure antenna 120i indicates “7”. The non-conductive portion 122j has the shape of the number “8” displayed in the number display area 111j, and the figure antenna 120j indicates “8”. Further, the non-conductive portion 122k has a shape of a number “0” displayed in the number display area 111k, and the figure antenna 120k indicates “0”. The non-conductive portion 122l has the shape of the number “6” displayed in the number display area 111l, and the figure antenna 120l indicates “6”.

  In FIG. 5B, the heights of the numbers due to the shapes of the non-conductive portions 122a to 122l are the same, but the resonance frequencies of the figure antennas 120a to 120l in the number display areas 111a to 111l are the numbers “ 1 ”,“ 2 ”,“ 3 ”,“ 4 ”,“ 5 ”,“ 6 ”,“ 7 ”,“ 8 ”,“ 9 ”,“ 0 ”are set appropriately so that their heights are different from each other. Has been.

  In the delivery slip 30 configured as described above, the inquiry number display field 34 is given a number that constitutes the inquiry number displayed in the inquiry number display field 34, as in the ID tag 1 shown in FIG. Number display areas 111a to 111l are provided, and in each of the number display areas 111a to 111l, figure antennas 120a to 120l including conductive parts 121a to 121l and non-conductive parts 122a to 122l are formed. Yes. And each non-conductive part 122a-122l becomes the shape of the number displayed on each of the number display area 111a-111l, Therefore The inquiry number can be visually recognized. In addition, the resonance frequencies of the figure antennas 120a to 120l in the number display areas 111a to 111l are numbers “1”, “2”, “3”, “4”, “5”, “6”, “7”, “8”. The numbers “1”, “2”, “3”, “4”, “5”, “6”, “7”, “8” are different for each of “9” and “0”. , “9”, “0” resonance frequencies for numbers “1”, “2”, “3”, “4”, “5”, “6”, “7”, “8”, “9”, By associating with “0”, the numbers given to the number display areas 111a to 111l can be recognized by detecting the resonance frequencies of the figure antennas 120a to 120l in the number display areas 111a to 111l. , By recognizing the arrangement order, displayed in the inquiry number display field 34 Have combined number can be identified.

  FIG. 6 is a diagram showing an embodiment of the identification system of the present invention, which recognizes the inquiry number displayed in the inquiry number display field 34 of the delivery slip 30 shown in FIG.

  As shown in FIG. 6, the identification system in this embodiment includes an antenna 41, an electromagnetic wave radiation unit 42, a frequency detection unit 43, an ID database 44, an individual ID recognition unit 45 serving as a first recognition unit, and a second unit. ID recognition unit 46 serving as a recognition means.

  The electromagnetic wave radiating unit 42 sweeps the frequency band including the resonance frequency of the figure antennas 120a to 120l in the number display areas 111a to 111l with respect to each of the number display areas 111a to 111l. Radiates through. In the electromagnetic wave radiation unit 42, the number display area is not provided for each of the number display areas 111a to 111l, instead of sweeping the frequency band including the resonance frequency of the figure antennas 120a to 120l in the number display areas 111a to 111l. It is good also as a structure which radiates | emits the electromagnetic wave of the resonance frequency of the figure antennas 120a-120l in 111a-111l simultaneously. That is, the electromagnetic wave radiation unit 42 radiates electromagnetic waves of a plurality of frequencies including the resonance frequencies of the figure antennas 120a to 120l in the number display areas 111a to 111l to the number display areas 111a to 111l via the antenna 41. Is.

  The frequency detector 43 detects the reflected wave with respect to the electromagnetic wave radiated from the electromagnetic wave radiation unit 42 for each of the number display areas 111a to 111l via the antenna 41 for each of the number display areas 111a to 111l. The resonance frequencies of the figure antennas 120a to 120l in the number display areas 111a to 111l are detected.

  As shown in FIG. 4, in the ID database 44, the resonance frequencies of the figure antennas 120a to 120l set so as to be different from one another for each number and the corresponding number are registered. In addition, the resonance frequency when the figure antennas 120a to 120l do not exist is registered.

  The individual ID recognition unit 45 recognizes a number associated with the resonance frequency detected by the frequency detection unit 43 in the ID database 44. That is, the individual ID recognition unit 45 recognizes the numbers displayed in the number display areas 111a to 111l for each of the number display areas 111a to 111l using the resonance frequency detected by the frequency detection unit 43.

  The ID recognition unit 46 displays the numbers recognized by the individual ID recognition unit 45 in the inquiry number display column 34 by arranging the resonance frequencies corresponding to the numbers in the order in which the frequency detection unit 43 detects the resonance frequencies. Recognize the inquiry number.

  Hereinafter, a method for recognizing the inquiry number displayed in the inquiry number display column 34 of the delivery slip 30 shown in FIG. 5 in the identification system configured as described above will be described.

  FIG. 7 is a diagram for explaining a method of recognizing the inquiry number displayed in the inquiry number display field 34 of the delivery slip 30 shown in FIG. 5 in the identification system shown in FIG. The figure which shows the state of the delivery slip 30 at the time of an inquiry number being recognized, (b)-(e) shows the detection state via the antenna 41 of the electromagnetic wave radiation | emission through the antenna 41, and the reflected wave from a figure antenna. FIG.

  The electromagnetic wave radiated from the electromagnetic wave radiation part 42 is radiated through the antenna 41 onto the conveyor 3 on which the delivery 2 to which the delivery slip 30 is attached as shown in FIG. At that time, the electromagnetic wave radiation unit 42 emits the electromagnetic wave so as to sweep the frequency band including the resonance frequency of the figure antenna in the number display areas 111a to 111l. However, the figure antenna exists in the region where the electromagnetic wave is emitted. If not, no reflected wave is detected. Then, the individual ID recognition unit 45 determines that the figure antenna does not exist in the region where the electromagnetic wave is radiated. In addition, the antenna 41 is not restricted to what is provided above the conveyor 3 as shown to Fig.7 (a). For example, the electromagnetic wave may be radiated through the conveyor 3 to the delivery 2 that is provided below the conveyor 3 and is conveyed on the conveyor 3, or may be provided on the side of the conveyor 3.

  Then, as shown in FIG. 7A, the delivery item 2 with the delivery slip 30 attached is conveyed on the conveyor 3 so that the inquiry number display column 34 faces the antenna 41. At this time, as described above, the inquiry number display field 34 is provided with the number display areas 111a to 111l. When the delivery 2 is conveyed on the conveyor 3, the antenna 41 is connected to the number display area. The number display areas 111a to 111l are sequentially opposed from the 111a side.

  When the antenna 41 first faces the number display area 111a, as shown in FIG. 7B, the electromagnetic wave radiated from the electromagnetic wave radiation unit 42 is radiated to the figure antenna 120a in the number display area 111a via the antenna 41. Here, the antenna 41 has directivity so that electromagnetic waves can be irradiated to each of the figure antennas 120a to 120l in the number display areas 111a to 111l. When the electromagnetic wave radiated from the electromagnetic wave radiation part 42 is radiated to the figure antenna 120 a via the antenna 41, the reflected wave from the figure antenna 120 a is detected via the antenna 41. At this time, electromagnetic waves are radiated from the electromagnetic wave radiation part 42 so as to sweep the frequency band including the resonance frequencies of the figure antennas 120a to 120l with the antenna 41 facing the number display area 111a. The resonance frequency of the figure antenna 120a is detected by the frequency detector 43 by the reflected wave from the figure antenna 120a. In this example, since the number displayed by the figure antenna 120a in the number display area 111a is “2”, referring to FIG. 4, resonance frequencies of 5.9 GHz and 6.3 GHz are detected. Then, the individual ID recognition unit 45 refers to the ID database 44 and recognizes the number “2” associated with the resonance frequencies of 5.9 GHz and 6.3 GHz.

  When the delivery 2 is conveyed on the conveyor 3 and then the antenna 41 faces the number display area 111b, the electromagnetic wave radiated from the electromagnetic wave radiating unit 42 is transmitted to the antenna 41 as shown in FIG. Through the figure antenna 120b in the number display area 111b, and the reflected wave of 120b is detected through the antenna 41 from the figure antenna. At this time, as described above, the electromagnetic wave radiation unit 42 sweeps the frequency band including the resonance frequencies of the figure antennas 120a to 120l in the number display areas 111a to 111l with the antenna 41 facing the number display area 111b. The electromagnetic wave is radiated, and the resonance frequency of the figure antenna 120b is detected by the frequency detector 43 by the reflected wave from the figure antenna 120b. In this example, since the number displayed by the figure antenna 120b in the number display area 111b is “3”, referring to FIG. 4, resonance frequencies of 5.9 GHz and 6.4 GHz are detected. Then, the individual ID recognition unit 45 refers to the ID database 44 and recognizes the number “3” associated with the resonance frequencies of 5.9 GHz and 6.4 GHz.

  When the delivery 2 is conveyed on the conveyor 3 and then the antenna 41 faces the number display area 111c, the electromagnetic wave radiated from the electromagnetic wave radiating section 42 is transmitted to the antenna 41 as shown in FIG. The figure antenna 120c in the number display area 111c is radiated and the reflected wave from the figure antenna 120c is detected via the antenna 41. At this time, similarly to the above, the electromagnetic wave radiation unit 42 sweeps the frequency band including the resonance frequencies of the figure antennas 120a to 120l in the number display areas 111a to 111l in a state where the antenna 41 faces the number display area 111c. The electromagnetic wave is radiated, and thereby the resonance frequency of the figure antenna 120c is detected by the frequency detector 43 by the reflected wave from the figure antenna 120c. In this example, since the number displayed by the figure antenna 120c in the number display area 111c is “1”, referring to FIG. 4, resonance frequencies of 6.1 GHz and 5.2 GHz are detected. Then, the individual ID recognition unit 45 refers to the ID database 44 and recognizes the number “1” associated with the resonance frequencies of 6.1 GHz and 5.2 GHz.

  When the delivery 2 is conveyed on the conveyor 3 and then the antenna 41 faces the number display area 111d, the electromagnetic wave radiated from the electromagnetic wave radiating unit 42 is transmitted to the antenna 41 as shown in FIG. The figure antenna 120d in the number display area 111d is radiated and the reflected wave from the figure antenna 120d is detected via the antenna 41. At this time, similarly to the above, the electromagnetic wave radiation unit 42 sweeps the frequency band including the resonance frequencies of the figure antennas 120a to 120l in the number display areas 111a to 111l in a state where the antenna 41 faces the number display area 111d. The electromagnetic wave is radiated, and thereby the resonance frequency of the figure antenna 120d is detected by the frequency detector 43 by the reflected wave from the figure antenna 120d. In this example, since the number displayed by the figure antenna 120d in the number display area 111d is “3”, referring to FIG. 4, resonance frequencies of 5.9 GHz and 6.4 GHz are detected. Then, the individual ID recognition unit 45 refers to the ID database 44 and recognizes the number “3” associated with the resonance frequencies of 5.9 GHz and 6.4 GHz.

  Thereafter, similarly, for each of the number display areas 111e to 111l, the resonance frequency of the figure antennas 120e to 120l is sequentially detected by the frequency detection unit 43, whereby the figure antennas 120e to 120l are displayed in the number display areas 111e to 111l. The individual ID recognizing unit 45 recognizes the number displayed by.

  When the numbers displayed in the number display areas 111a to 111l are respectively recognized by the individual ID recognition unit 45, the numbers recognized by the individual ID recognition unit 45 in the ID recognition unit 46 are resonances corresponding to the numbers. The frequencies are arranged in the order detected by the frequency detector 43. In this example, in the frequency detection unit 43, a resonance frequency corresponding to “2”, a resonance frequency corresponding to “3”, a resonance frequency corresponding to “1”, a resonance frequency corresponding to “3”, and “4” Resonance frequency corresponding to “9”, resonance frequency corresponding to “4”, resonance frequency corresponding to “5”, resonance frequency corresponding to “7”, resonance frequency corresponding to “8” , The resonance frequency corresponding to “0” and the resonance frequency corresponding to “6” are detected in this order, so that these numbers are “2”, “3”, “1”, “3” in the ID recognition unit 46. "4", "9", "4", "5", "7", "8", "0", "6" are arranged in this order, so that the numbers "2", "3" , “1”, “3”, “4”, “9”, “4”, “5”, “7”, “8”, “0”, “6”. Formed by combining in the order "231349457806" is, would be recognized as a tracking number that appears in the query number display column 34.

  Moreover, since this inquiry number can be recognized visually by the shape of the non-conductive parts 122a to 122l of the number display areas 111a to 111l, as described above, the figure antennas 120a to 120l in the number display areas 111a to 111l Even if the inquiry number cannot be recognized due to the resonance frequency, it can be visually recognized.

  Here, when the delivery slip 30 is affixed to the side surface of the delivery item 2, the antenna 41 and the figure antennas 120a to 120l in the number display areas 111a to 111l do not face each other.

  FIG. 8 is a diagram showing the frequency characteristics when the antenna 41 shown in FIG. 6 is not directly facing the figure antenna, and (a) shows the frequency characteristics when the figure antenna shows the number “1”. FIG. 8B is a diagram illustrating frequency characteristics when the figure antenna indicates the numeral “2”.

  As shown in FIG. 8A, when the figure antenna indicates the number “1”, the frequency characteristic (solid line) when the figure antenna faces the antenna 41 and the figure antenna is perpendicular to the antenna 41. If the figure antenna is oriented in a direction perpendicular to the antenna 41, the communication distance is shorter, but the resonance points are almost the same. It has become.

  As shown in FIG. 8B, when the figure antenna indicates the number “2”, the frequency characteristic (solid line) when the figure antenna faces the antenna 41 and the figure antenna with respect to the antenna 41 are shown. When compared with the frequency characteristics (broken line) when directed in the vertical direction, the second resonance point is shifted.

  As described above, the resonance point may be shifted between the case where the figure antenna faces the antenna 41 and the case where the figure antenna faces in a direction perpendicular to the antenna 41. By registering the deviation in the database, the inquiry number can be accurately recognized in the same manner as described above even when the delivery slip 30 is affixed to the side of the delivery 2. When the figure antenna is oriented in a direction perpendicular to the antenna 41, the communication distance is further shortened when the side on which the figure antenna is opened faces the antenna 41. Since this is the same as the case where the side that is not open faces the antenna 41, the shift of the resonance point may be registered in the database.

  Further, for example, in the inquiry number display field 34 in the delivery slip 30 shown in FIG. 5, there are figure antennas on both sides like the figure antenna 120b in the number display area 111b, and the figure antenna in the number display area 111a. Even if there is a figure antenna on only one side such as 120a, the frequency characteristics will be slightly different, but also by registering the resonance point in the database, the inquiry number can be changed in the same way as above. It can be recognized accurately. This is not limited to the case where the figure antenna exists on both sides or one side in the left-right direction of the figure antenna, but can also be applied to the case where the figure antenna exists on both sides or one side in the vertical direction of the figure antenna.

  Note that the configuration of the identification object identified by the identification system of the present invention may be applied to the postal code of a postcard as well as to the inquiry number of the delivery slip 30 as described above. Further, the identification information given as the figure antenna is not limited to the numbers described above, but can be applied to characters, symbols, and the like. Furthermore, if the antenna for identifying each digit constituting the ID such as the inquiry number described above is an antenna having a resonant frequency corresponding to the digit, character, symbol, etc. of the digit, the resonant frequency Since these can be recognized by detecting, numbers, letters, symbols, etc. may not be recognized visually.

  Further, the number display areas 111a to 111l in the inquiry number display column 34 and the antenna 41 are made to face each other depending on the transport direction of the delivery 2 to which the delivery slip 30 is attached, the mounting state of the delivery 2 on the conveyor 3, and the like. The order may be reversed from that described above. In that case, in the ID recognition unit 46, the numbers recognized by the individual ID recognition unit 45 are arranged in an order opposite to the order in which the resonance frequency corresponding to the numbers is detected by the frequency detection unit 43. The inquiry number displayed in the inquiry number display field 34 is recognized. In such a configuration, in the inquiry number display field 34 of the delivery slip 30, the order in which the antennas 41 face each other in the number display areas 120 a to 120 l, that is, the direction in which the electromagnetic waves should be radiated from the electromagnetic wave radiation unit 42. It can be considered that a region having a reference resonance frequency is provided at the top as one of the number display areas.

  FIG. 9 is a diagram showing another example of the inquiry number display field 34 of the delivery slip 30 shown in FIG.

  As shown in FIG. 9, a region where a reference antenna 125 made of only a conductive portion is formed is provided adjacent to the number display area 111a. Then, the resonance frequencies in that region are registered in the ID database 44, and the ID recognition unit 46 rearranges the arranged numbers starting from the side where the reference resonance frequency is detected by the frequency detection unit 43. For example, in the example shown in FIG. 4, since the resonance frequency of the reference antenna 125 including only the conductive portion is 6.0 GHz, the antenna 41 is arranged by rearranging the side where the 6.0 GHz resonance frequency is detected. Even when the facing order is the reverse of the order in which the antennas 41 should face each other in the number display areas 120a to 120l, the inquiry number displayed in the inquiry number display column 34 is accurately recognized. be able to.

  As such a configuration, the number display areas 120a to 120l are adjacent to the number display area 111l in the tail of the direction in which the electromagnetic wave is to be emitted from the electromagnetic wave radiation unit 42, that is, in the delivery slip 30 of FIG. Then, a region having a reference resonance frequency is provided as one of the number display areas. In the ID recognition unit 46, the arranged numbers are displayed on the side where the reference resonance frequency is detected by the frequency detection unit 43. May be rearranged as the tail.

  Moreover, even when the conveyance speed of the conveyor 3 and the size of the number display areas 111a to 111l change, the frequency sweep operation and the frequency of the resonance frequency detection operation in the electromagnetic wave radiation unit 42 and the frequency detection unit 43 change accordingly. By doing so, the inquiry number displayed in the inquiry number display field 34 can be recognized.

  The initial position of the delivery item 2 when recognizing the inquiry number is the number display area 111a or the number display area 111l at the end of the number display areas 111a to 111l provided in the inquiry number display field 34. May be set so that the resonance frequency of the figure antenna in the number display areas 111a and 111l is not detected a plurality of times.

DESCRIPTION OF SYMBOLS 1 ID tag 2 Deliverable thing 3 Conveyor 10 Base base material 11a-11j, 111a-111l Number display area 20a-20j, 120a-120j Figure antenna 21a-21j, 121a, 121j Conductive part 22a-22j, 122a-122j Nonconductive part 23 End 24 Conductor 30 Delivery slip 31 Delivery destination information display field 32 Delivery source information display field 33 Product name display field 34 Inquiry number display field 41 Antenna 42 Radio wave radiation part 43 Frequency detection part 44 ID database 45 Individual ID recognition part 46 ID Recognition unit 125 Reference antenna

Claims (2)

An identification body having a plurality of information carrying areas to which first identification information that can be recognized by the resonance frequency of the antenna is formed is provided to each of the plurality of information carrying areas of the identification body. An identification system for identifying using second identification information formed by combining the first identification information,
A database associating the resonant frequency of the antenna with the first identification information;
Electromagnetic wave radiating means for sequentially radiating electromagnetic waves having a plurality of frequencies including the resonance frequency to each of a plurality of information-carrying regions included in one identifier;
For each of the plurality of information-carrying regions, frequency detection means for sequentially detecting a resonance frequency of the antenna by a reflected wave from the antenna with respect to the radiated electromagnetic wave;
First recognition means for recognizing first identification information associated with the detected resonance frequency in the database;
A second for recognizing the second identification information by arranging the recognized first identification information in accordance with the order in which the resonance frequency corresponding to the first identification information is detected by the frequency detection means; A recognition system. The identification system according to claim 1,
The discriminator has a region having a reference resonance frequency, and the plurality of information carrying regions at the head or the tail in a direction in which the electromagnetic wave radiation means should sequentially emit electromagnetic waves to the plurality of information carrying regions. As one of the
The second recognizing means sets the first identification information arranged as the second identification information by setting the side where the reference resonance frequency is detected by the frequency detecting means as a head or tail. Recognition system.

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