JP2004039173A - Data library recognition system - Google Patents

Abstract

An object of the present invention is to provide a data library recognizing device, a data library recognizing method, and a data library recognizing system capable of efficiently recognizing a storage position of a cartridge having a recording medium capable of storing data in a library. .
A data library recognizing device according to the present invention is provided corresponding to each of a storage portion for storing a cartridge having a recording medium capable of storing data and a storage position of the cartridge, and transmits data from the cartridge. A plurality of pattern antennas 12b for wirelessly receiving identification information for identifying the cartridge 11 or data; and a reader / writer unit 13 for recognizing a storage position of the data in the library 10 based on the identification information received by the pattern antenna 12b. It is provided with.
[Selection diagram] Fig. 1

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a data library recognizing device, a data library recognizing method, and a data library recognizing system for recognizing a storage position of a cartridge having a recording medium capable of storing data in a library.
[0002]
[Prior art]
2. Description of the Related Art Conventionally, as a library system of a tape cartridge for backup of a computer, there is a library system using RFID (Radio Frequency Identification). When RFID is used in the library system, as shown in FIG. 10, a tape cartridge 104 is stored in a library 101 in which a drive unit 103 is provided. In this library system, the storage position of the tape cartridge 104 is recognized by scanning by moving the scan unit 102 mechanically. As shown in FIG. 11, the RFID tag 105 is built in the tape cartridge 104. The scanning unit 102 reads the RFID tag 105 and searches for a desired tape cartridge 104. As shown in FIG. 12, the RFID tag 105 is formed by forming an RFID chip 111 and an antenna coil 112 connected to the RFID chip 111 on a base material 110. The antenna coil 112 transmits the identification information stored in the RFID chip 111 to the scan unit 102.
[0003]
As shown in FIG. 13, a reader / writer antenna 107 is provided on a surface of the scan unit 102 facing the tape cartridge 104. The scan unit 102 transmits a radio wave to the RFID tag 105 via the reader / writer antenna 107. The RFID tag 105 receives a radio wave via the antenna coil 112, and power is supplied to the RFID chip 111 by the received radio wave. When power is supplied to the RFID chip 111, the identification information stored in the RFID chip 111 is transmitted to the scan unit 102 by radio waves via the antenna coil 112. The scan unit 102 that has received the identification information as a radio wave from the RFID chip 111 determines whether or not the tape cartridge 104 that has just read the identification information is the desired tape cartridge 104 based on the received identification information. If the tape cartridge 104 is not the desired tape cartridge 104, the other tape cartridges 104 are scanned until the desired tape cartridge is found.
[0004]
When the scan unit 102 reads the identification information stored in the RFID tag 105 built in the tape cartridge 104 and finds the desired tape cartridge 104, the robot arm 106 provided in the scan unit 102 performs tape search as shown in FIG. Remove the cartridge 104. The removed tape cartridge 104 is moved to the drive unit 103, and the data stored on the stored tape is read.
[0005]
However, a mechanical scanning time is required for the scan unit 102 to find a desired tape cartridge 104, and the tape unit 104 cannot be efficiently searched using the scan unit 102. Further, when the RFID tag 105 of the tape cartridge 104 is read, recognition time is required for the scanning unit 102 to read and recognize the RFID tag 105, so that more unnecessary time is spent. Furthermore, since the RFID tag 105 needs an externally attached relatively large antenna for communication with the scan unit 102, the RFID tag 105 communicates with the scan unit 102 to identify the location of the tape cartridge 104. It is necessary to increase the pitch at which the tape cartridges 104 are arranged in consideration of the collision of communication between adjacent radio waves to be transmitted and received. Further, it is possible to identify the RFIDs in the same field by utilizing the anti-collision function, but it is difficult to identify the storage location. Therefore, there is a limit in reducing the pitch at which the tape cartridges 104 are arranged in the library 101, and there is a limit in the storage efficiency of the tape cartridge 101.
[0006]
[Problems to be solved by the invention]
As described above, in the conventional data library recognizing device, the scanning unit is mechanically moved to scan and read the RFID tag to recognize the storage position of the cartridge, so that the storage position of the cartridge can be recognized efficiently. There was a problem that it was not possible.
[0007]
The present invention has been made to solve such a problem, and a data library recognition device and a data library capable of efficiently recognizing a storage position of a cartridge having a recording medium capable of storing data in a library. It is an object to provide a recognition method and a data library recognition system.
[0008]
[Means for Solving the Problems]
A data library recognizing device according to the present invention is a data library recognizing device that recognizes a data storage position in a library that stores a cartridge having a recording medium capable of storing data, wherein a storage unit that stores the cartridge, A plurality of receiving means (for example, the pattern antenna according to the embodiment of the present invention) provided corresponding to each of the storage positions of the cartridge and wirelessly receiving identification information transmitted from the cartridge and identifying the cartridge or data. 12b) and a recognizing means (for example, the reader / writer unit 13 in the embodiment of the present invention) for recognizing the storage position of the data based on the identification information received by the receiving means. With such a configuration, the storage position of the cartridge can be recognized efficiently.
[0009]
Further, in the data library recognizing device according to the present invention, the receiving means has an antenna coil for wirelessly receiving, and the antenna coil is provided corresponding to a storage position of the cartridge. Thus, the identification information is received by the antenna coil corresponding to the storage position of the cartridge, and the storage position of the cartridge can be efficiently recognized.
[0010]
Still further, the data library recognition device according to the present invention receives the identification information by sequentially scanning reception operations of the plurality of reception units. Thereby, the receiving operation of the identification information of the cartridge is sequentially scanned, and the identification information of each cartridge can be efficiently received.
[0011]
Preferably, the data library recognizing device according to the present invention includes a parallel processing circuit that performs receiving operations of the plurality of receiving units in parallel. Thereby, the identification information of a plurality of cartridges can be obtained simultaneously.
[0012]
Further, in the data library device according to the present invention, the recognizing unit includes a moving unit (for example, the robot arm 14 according to the embodiment of the present invention) for moving the cartridge to be taken out of the library or stored in the library. The communication of the identification information is performed between the two, and the operation of the moving means is controlled based on the identification information. Thereby, the storage position of the cartridge can be efficiently recognized, and the cartridge can be moved.
[0013]
A data library recognition method according to the present invention is a data library recognition method for recognizing a data storage position in a library that stores a cartridge having a recording medium capable of storing data, wherein the data library is transmitted from the cartridge, A receiving step of receiving wireless information including identification information for identifying data by a plurality of receiving means (for example, the pattern antenna 12b in the embodiment of the present invention) provided corresponding to the storage position of the cartridge; And a recognition step of recognizing a storage position of the data based on the identification information received by the computer. With such a method, the storage position of the cartridge can be efficiently recognized.
[0014]
Further, in the data library recognition method according to the present invention, the wireless information is received by sequentially scanning the receiving operations of the plurality of receiving units. Thereby, the receiving operation of the identification information of the cartridge is sequentially scanned, and the identification information of each cartridge can be efficiently received.
[0015]
Preferably, in the data library recognition method according to the present invention, the receiving operations of the plurality of receiving units are performed by parallel processing. Thereby, the identification information of a plurality of cartridges can be obtained simultaneously.
[0016]
A data recognition system according to the present invention is a data library recognition system that includes a cartridge that stores a recording medium capable of storing data, and a library that stores the cartridge, and recognizes a data storage position in the library. The cartridge includes identification information storage means for storing identification information for identifying the cartridge or data (for example, the coil-on-chip 21 in the embodiment of the present invention), and transmission means for wirelessly transmitting the identification information ( For example, the library includes the coil-on-chip 21) according to the embodiment of the present invention, and the library is provided corresponding to each of a storage unit that stores the cartridge and a storage position of the cartridge, and is transmitted from the cartridge. A plurality of receiving means for receiving the identification information wirelessly (for example, according to the present invention). And a recognition unit (for example, the reader / writer unit 13 in the embodiment of the present invention) for recognizing the storage position of the data based on the identification information received by the receiving unit. Things. With such a configuration, the storage position of the cartridge can be recognized efficiently.
[0017]
In the data library recognition system according to the present invention, the identification information storage means is an IC element for storing information for specifying the data including the identification information, and the transmission means is provided on the IC element. And an antenna coil for transmitting the information. This allows the identification information storage means and the transmission means to be integrally formed and built into the cartridge.
[0018]
Further, in the data library recognition system according to the present invention, the receiving means has an antenna coil for wirelessly receiving, and the antenna coil is provided corresponding to a storage position of the cartridge. Thus, the identification information is received by the antenna coil corresponding to the storage position of the cartridge, and the storage position of the cartridge can be efficiently recognized.
[0019]
Still further, in the data library recognition system according to the present invention, the identification information is received by sequentially scanning the receiving operations of the plurality of receiving means. Thereby, the receiving operation of the identification information of the cartridge is sequentially scanned, and the identification information of each cartridge can be efficiently received.
[0020]
Preferably, the data library recognition system according to the present invention includes a parallel processing circuit that performs receiving operations of the plurality of receiving units in parallel. Thereby, the identification information of a plurality of cartridges can be obtained simultaneously.
[0021]
Further, in the data library recognition system according to the present invention, the recognition unit communicates the identification information with a moving unit that moves to take out the cartridge from the library or to store the cartridge in the library. The operation of the means is controlled based on the identification information. Thereby, the storage position of the cartridge can be efficiently recognized, and the cartridge can be moved.
[0022]
A data library recognizing method according to the present invention is a data library recognizing method including a cartridge for storing a recording medium capable of storing data and a library for storing the cartridge, and recognizing a data storage position in the library. Transmitting a radio signal including identification information for identifying the cartridge or data to the library, wherein the library is transmitted from the cartridge, and the radio information is stored in a storage position of the cartridge. A receiving step of receiving by a plurality of receiving means provided correspondingly (for example, the pattern antenna 12b in the embodiment of the present invention), and recognizing a storage position of the data based on identification information received by the receiving means. And a recognition step. With such a method, the storage position of the cartridge can be efficiently recognized.
[0023]
Further, in the data library recognition method according to the present invention, the wireless information is received by sequentially scanning the receiving operations of the plurality of receiving units. Thereby, the receiving operation of the identification information of the cartridge is sequentially scanned, and the identification information of each cartridge can be efficiently received.
[0024]
Preferably, in the data library recognition method according to the present invention, the receiving operations of the plurality of receiving units are performed by parallel processing. Thereby, the identification information of a plurality of cartridges can be obtained simultaneously.
[0025]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
[0026]
In the embodiment of the present invention, after describing the data library recognition system of the present embodiment, a coil-on-chip used in the present embodiment will be described.
[0027]
First, a data library recognition system according to an embodiment of the present invention will be described, and a structure of a data library device which is one of the components will be described. FIG. 1 is a schematic diagram illustrating an example of a data library recognition system according to an embodiment of the present invention. As shown in FIG. 1, the data library recognition system according to the present embodiment includes a library device 10 and a cartridge 11 housed in the library device 10. Further, a library device 10 which is one component of the data library recognition system is provided with an antenna array 12 close to a cartridge 11, a reader / writer unit 13 is connected to the antenna array 12, and a cartridge is attached to the reader / writer unit 13. A robot arm 14 for taking the 11 in and out of the library device 10 is connected.
[0028]
The library device 10 that stores the cartridge 11 is a general housing that stores the cartridge 11 in which a recording medium on which data is recorded is stored. In FIG. 1, the shape of the library device 10 is a substantially rectangular parallelepiped shape. However, the library device 10 may be changed according to the shape of the cartridge 11, or the shape of the peripheral portion may be changed by setting the place where the cartridge 11 is stored to be a substantially rectangular parallelepiped shape. May be. Further, the library device 10 can be formed by using metal or synthetic resin, but it is preferable that the library device 10 be formed firmly because it accommodates a plurality of cartridges 11.
[0029]
As shown in FIG. 1, the library device 10 is provided with a storage section in which the cartridge 11 is stored. For example, in FIG. 1, the storage units are formed in storage shelves formed in two stages and are formed at every pitch L, and the cartridges 11 are stored in the storage shelves of the library device 10 which are divided in a matrix. The structure of the storage unit is determined by the manner in which the cartridge 11 is stored in the library device 10. For example, when storing the cartridge 11 having a substantially rectangular parallelepiped shape, a storage shelf is formed in the library device 10 having a substantially rectangular parallelepiped shape. , And is preferably formed by being divided for every arrangement pitch L. Although not shown in FIG. 1, a guide that divides the storage section and determines the storage position of the cartridge 11 can be provided on the storage shelf. For example, a guide is provided on the storage shelf, a storage wall having a through hole is provided at a location where the antenna array 12 is provided, or upper and lower storage shelves for stabilizing the cartridge 11 from above and below in FIG. A guide can be provided.
[0030]
The cartridge 11 is stored in the library device 10 or the cartridge 11 is removed from the library device 10. For example, a storage wall is provided so as to stop when the cartridge 11 is stored on one of the entire surface or the back surface in FIG. The cartridge 11 may be taken in and out by another person, or may be made to be able to be taken in and out from both sides without providing a storage wall. As will be described later, in the present embodiment, the scanning unit for reading the cartridge 11 is not provided on the take-out surface of the cartridge 11 unlike the related art, so that the scanning unit does not take up space and can be viewed from both sides of the library device 10. A flexible and convenient library device 10 that can be put in and taken out can be realized.
[0031]
When a storage shelf for storing the cartridge 11 is provided in the library device 10, for example, the antenna array 12 is arranged on the storage shelf. As shown in FIG. 2, the antenna array 12 has a base material 12a and a pattern antenna 12b formed on the base material 12a. The base member 12a is formed of an insulating member such as plastic, and the pattern antenna 12b is formed of a conductive member so that a current flows. The shape of the base material 12a may be, for example, a substantially square shape as shown in FIG. 1, or may be a shape having irregularities according to the shape of the storage section of the library device 10 or the shape of the cartridge. The pattern antenna 12b has a desired size, shape, self-inductance, and mutual inductance according to the arrangement with the coil-on-chip 21, the mounting area, and other conditions. Further, in FIG. 2, for example, the shape of the coil is rectangular when viewed from above, but may be circular, square, elliptical, or the like. Although the pattern antenna 12b is disposed on the base material 12a, the pattern antenna 12b may be disposed directly on the storage unit on the storage shelf of the library device 10.
[0032]
As shown in FIG. 1, the pattern antenna 12b is formed so as to correspond to a storage position where the cartridge 11 is stored when the antenna array 12 is provided in the library device 10. As shown in FIG. 1, when the cartridge 11 is stored in a storage position provided in the library device 10 in advance, it faces a coil-on-chip 21 formed on the bottom of the cartridge 11 as described later, and Radio waves are transmitted to the coil-on-chip 21 to supply power. Therefore, when the cartridge 11 is stored in the storage position of the library device 10, the pattern antenna 12 b is arranged on the base material 12 a so as to face the coil-on-chip 21. In FIG. 1, for example, since the cartridges 11 are stored in a matrix on the library device 10, the pattern antenna 12b is substantially fixed on the base material 12a so as to coincide with the storage position in the row direction of the matrix storage shelf. They are arranged at intervals (arrangement pitch L).
[0033]
The antenna array 12 only needs to have the pattern antenna 12 b facing the coil-on-chip 21 of the cartridge 11 when the cartridge 11 is stored in the library device 10. Depending on the installation position of the coil-on-chip 21 provided on the cartridge 11, it can be provided at various locations of the library device 10. Further, the pattern antenna 12b on the base material 12a only needs to face the coil-on-chip 21 of the cartridge 11 when the cartridge 11 is housed in the library device 10; Various arrangements can be made according to the shape of the storage section and the installation position of the coil-on-chip 21 provided on the cartridge 11 on the cartridge 11.
[0034]
The cartridge 11 is a general housing that stores a recording medium for recording data, and can be formed using metal or synthetic resin. The shape of the cartridge 11 can be various shapes depending on the shape of the recording medium housed therein. As shown in FIG. 1, the cartridge 11 can be efficiently housed in the library device 10 by being formed in a substantially rectangular parallelepiped shape. . The recording medium that is stored in the cartridge 11 and records data is, for example, a medium that can generally record text and images, such as a tape, a 3.5-inch disk, a CD-ROM, and an MO.
[0035]
As shown in FIG. 3, a coil-on-chip 21 is formed on a cartridge housing 11a of the cartridge 11. The coil-on-chip 21 may be formed at any position on the cartridge housing 11a. For example, as shown in FIG. 1, a matrix-shaped storage shelf is provided in the library device 10 to store the cartridges 11 in a matrix. In this case, the coil-on-chip 21 and the pattern antenna 12b are preferably formed at the bottom of the cartridge housing 11a in order to bring the pattern antenna 12b closer to improve reception of radio waves. This ensures that the cartridge 11 comes into contact with the bottom surface of the storage shelf by its own weight, so that the distance between the antenna array 12 and the cartridge 11 can be made constant.
[0036]
The coil-on-chip 21 has an IC element and an antenna coil connected to the IC element. The IC element includes a memory for storing data and information such as identification information for identifying the cartridge 11, and a logic control circuit such as a clock and a CPU. The memory is composed of a ROM, a RAM, an EEPROM, an FRAM or the like for storing data, and the logic control circuit is composed of a CPU or the like. The IC element can communicate with the reader / writer unit 13 based on the identification information, and the CPU can perform predetermined processing.
[0037]
Further, the IC element has a transmission / reception circuit including a demodulation circuit and a modulation circuit, and a power supply circuit capable of purchasing a received radio wave for power. The modulation circuit and the demodulation circuit are controlled by the logic control circuit and operate in synchronization with the clock. The coil-on-chip 21 does not include a battery, and the power supply circuit obtains its operating power from electromagnetic waves received by the antenna coil by electromagnetic induction. The demodulation circuit of the transmission / reception circuit restores the baseband signal to obtain data after detecting the received radio wave. In addition, the modulation circuit of the transmission / reception circuit changes a carrier wave according to transmission data to transmit data, and transmits the carrier wave to the antenna coil. As a modulation method, for example, ASK for changing the amplitude of a carrier (carrier) frequency, PSK for changing a phase, or the like can be used.
[0038]
The IC element has a pair of connection terminals to which an antenna coil made of copper or the like is connected. Further, the IC element and the antenna coil may be formed integrally. The antenna coil is connected to the IC element and is electromagnetically coupled to the pattern antenna 12b of the antenna array 12 in a non-contact manner when the cartridge 11 is stored in the library device 10. The antenna coil and the pattern antenna 12b are arranged close to each other or close to each other with a small gap, and the antenna coil functions as a communication unit in the coil-on-chip 21. When the cartridge 11 is housed in the library device 10, the antenna coil is arranged close to or close to the pattern antenna 12 b, so that the communication distance is very small compared to the size of the pattern antenna 12 b of the antenna array 12. . The antenna coil has a desired size, shape, self-inductance, and mutual inductance according to the arrangement with the pattern antenna 12b, the mounting area, and other conditions. For example, when viewed from above, the shape of the coil is not limited to a circle, but may be a square, an ellipse, or the like.
[0039]
As shown in FIG. 4, the coil-on-chip 21 is modularized and arranged on the cartridge housing 11 a of the cartridge 11 in the state of the mini-mold 22. As shown in FIG. 4A, the mini mold 22 is formed by covering the coil-on-chip 21 with a material such as rubber or resin. The material covering the coil-on-chip 21 is preferably an insulating material because the coil-on-chip 21 including the antenna coil and the IC element is covered in an electrically insulated state. Thereafter, as shown in FIG. 4B, the mini mold 22 is arranged on the cartridge housing 11a. At this time, as shown in FIG. 4B, the mini mold 22 is arranged near the surface of the cartridge housing 11a to transmit and receive radio waves to and from the pattern antenna 12b of the library device 10.
[0040]
The mini-mold 22 can be formed into various shapes, as long as it can protect the internal coil-on-chip 21. The shape is also determined by the arrangement of the mini mold 22 on the cartridge housing 11a. For example, as shown in FIG. 4A, the mini-mold 22 can have a substantially flat shape with the coil-on-chip 21 inside. In order to dispose the substantially flat mini-mold 22 in the cartridge housing 11a, for example, as shown in FIG. 4B, a concave portion for embedding the mini-mold 22 is formed on the bottom surface of the cartridge housing 11a.
[0041]
In FIG. 4, when embedding the mini-mold 22 in the recess of the cartridge housing 11a, one end of the mini-mold 22 is inserted avoiding a portion protruding from the inner wall of the recess, and the other end of the mini-mold 22 is distorted by distorting the mini-mold 22. Embed in the recess. As shown in FIG. 4B, when the mini-mold 22 is embedded in the recess, a part of the substantially flat mini-mold 22 presses the inner wall of the recess, and the mini-mold 22 is fixed inside the recess. At this time, the mini-mold 22 may be fixed by embedding an adhesive resin in the concave portion. As shown in FIG. 4 (a), the mini-mold 22 is configured such that a part of the substantially flat-shaped mini-mold 22 presses the inner wall of the concave portion, and the mini-mold 22 has a mini-mold at the projecting portion of the concave inner wall when one end of the mini-mold 22 is inserted into the concave portion. Since the mold 22 is not caught, a part of the substantially flat side wall can be formed to project. Further, since the mini-mold 22 is distorted when the mini-mold 22 is embedded in the concave portion, the coil-on-chip 21 can be formed of a flexible material such as plastic or rubber.
[0042]
Next, the operation of inserting and removing the cartridge 11 of the data library device will be described. When a voltage is applied from the reader / writer unit 13 to the antenna array 12, a current flows through the pattern antenna 12b. At this time, in order to apply a voltage to the antenna array 12, for example, scanning is sequentially performed on the pattern antenna 12b, and a voltage is applied to supply a current to each of the pattern antennas 12b. When a current flows through the pattern antenna 12b, it is electromagnetically coupled by the pattern antenna 12b and transmits a radio wave to the coil-on-chip 21 of the cartridge 11. The coil-on-chip 21 receives radio waves with an antenna coil connected to an internal IC element. When the antenna coil receives a radio wave, an antenna coil induced current is generated and flows, and the induced current causes a current to flow through the IC element. Since the induced current is an alternating current, it is changed to a direct current in the power supply circuit of the IC element, and a constant current for operating the IC element is obtained.
[0043]
When a current flows through the IC element, it passes through a demodulation circuit connected to the antenna coil and the input / output terminal, and identifies the cartridge 11 stored in the memory of the IC element and the data of the recording medium stored in the cartridge 11. Information such as information is read. The read information such as the identification information flows through the modulation circuit as a current to the antenna coil, and is emitted from the antenna coil to the outside as a radio wave. The emitted radio waves are received by the pattern antenna 12b on the antenna array 12, are electromagnetically coupled by the pattern antenna 12b, and an induced current is generated on the pattern antenna 12b. The reader / writer unit 13 identifies the type of the cartridge 11 and the type of data stored in the cartridge 11 based on the induced current.
[0044]
When the reader / writer unit 13 sequentially scans and applies a voltage to the pattern antenna 12b, the pattern antenna 12b receives a radio wave, and when the reader / writer unit 13 takes out the received radio wave as an induced current, the reader / writer unit 13 It can be recognized that the cartridge 11 is on the pattern antenna 12b. The reader / writer unit 13 recognizes the type of the cartridge 11 based on the identification information, and writes it in a library table of a storage device such as a hard disk. On the other hand, when a voltage is applied from the reader / writer unit 13 to the antenna array 12 and the pattern antenna 12b cannot extract an induced current without receiving a radio wave from the coil-on-chip 21, the pattern is It recognizes that there is no cartridge 11 on the antenna 12b, and fills in the library table.
[0045]
Here, there are various methods for identifying the cartridge 11 stored in the cartridge 11. For example, first, a cartridge table indicating correspondence between data and cartridges storing data is created in advance and stored in the storage device of the reader / writer unit 13. After the identification information for identifying each cartridge 11 is stored in the IC element of the coil-on-chip 21, the cartridge 11 is identified, and the cartridge table is referred to by the reader / writer unit 13, and the type of data is determined via the cartridge table. Can be identified. Further, for example, identification information for identifying the type of data itself is stored in the IC element of the coil-on-chip 21, the identification information for identifying the data itself is acquired by the reader / writer unit 13, and which cartridge 11 stores the data. It is also possible to identify the data itself regardless of the data.
[0046]
As described above, in the reader / writer unit 13, the existence of the cartridge 11 is managed, and the position of the cartridge 11 that stores what kind of data in which storage position is managed in the library table. Then, for example, when the desired data is taken out from the library device 10, the storage position of the cartridge 11 for storing the desired data is found from the library table, and the robot arm 14 is moved to the location of the cartridge 11. At this time, before moving the robot arm 14 to remove the cartridge 11, it is determined whether or not the cartridge 11 for storing desired data is in the storage position by sending a current to the pattern antenna 12b arranged in the storage position. It may be confirmed in advance by flowing.
[0047]
Lastly, a configuration and a manufacturing method of the IC element 30 used for the coil-on-chip 21 will be described. The IC element 30 is, for example, similar to the IC element disclosed in JP-A-2000-323643.
[0048]
First, the configuration of the IC element 30 will be described. As shown in FIGS. 5 and 6, the IC element 30 has a rectangular spiral formed on an input / output terminal 30a side of the IC element 30 via an insulating surface protection film 31 such as a silicon oxide film or a resin film. It is formed by integrally forming a coil 32 having a shape.
[0049]
The IC element 30 shown in FIG. 5 has the coil 32 formed only on the outer periphery except for the circuit forming portion 33, and prevents the generation of stray capacitance between the circuit formed on the IC element 30 and the coil 32. As a result, the efficiency of receiving power from the supply unit 43 described later can be improved.
[0050]
In order to receive a practically sufficient power supply and to secure communication characteristics with the supply unit 43, the coil 32 must have a line width of 7 μm or more, a line distance of 5 μm or less, and a number of turns of 20 or less. It is preferable to make the number of turns or more.
[0051]
The connection between the input / output terminal 30a of the IC element 30 and the coil 32 is made through a through hole 34 formed in the surface protection film 31. In this case, even if the formation position of the coil 32 is slightly displaced, the diameter or the width of the through hole 34 is changed as shown in FIG. 6 so that the connection between the input / output terminal 30a and the coil 32 is securely performed. More preferably, the line width is smaller than 32.
[0052]
The conductor forming the coil 32 has a multilayer structure including a metal deposition layer 35 and a metal plating layer 36, as shown in FIG. The metal deposition layer 35 and the metal plating layer 36 can be formed of any conductive metal. However, since the metal deposition layer 35 is relatively inexpensive and has high conductivity, the metal deposition layer 35 is made of aluminum, nickel, copper, and chromium. It is preferably formed of a selected metal or an alloy of two or more metals selected from these metal groups. In addition to a uniform single-layer structure, another layer structure in which different metal layers or alloy layers are laminated in multiple layers It can also be. On the other hand, the metal plating layer 36 is preferably formed of copper, and can be formed by electroless plating, electroplating, or precision electroforming.
[0053]
Next, a method for manufacturing the IC element 30 will be described with reference to FIGS. 7 is a plan view of a so-called completed wafer 37 completed through a predetermined process, FIG. 8 is a process diagram showing a method of manufacturing the IC element 30, and FIG. 9 is a completed view in which a required conductive pattern including a coil is formed. FIG. 4 is a plan view of a wafer 37.
[0054]
As shown in FIG. 7, on the completed wafer 37, a large number of IC element circuits 33 are formed at equal intervals on the inner peripheral portion except for the outermost peripheral portion. A surface protection film 31 is formed (see FIG. 8).
[0055]
In the method for manufacturing an IC element having the structure shown in FIG. 6, first, as shown in FIG. 8A, aluminum, an aluminum alloy, copper, The metal deposition layer 35 is formed uniformly using a copper alloy. Next, as shown in FIG. 8B, a photoresist layer 38 is uniformly formed on the metal deposition layer 35, and a mask 39 on which a required pattern including a coil is formed is formed on the formed photoresist layer 38. The photoresist layer 38 is exposed by applying light 40 having a predetermined wavelength from outside the mask 39. Thereafter, the exposed photoresist layer 38 is subjected to a developing process, and as shown in FIG. 8C, the exposed portion of the photoresist layer 38 is removed, and a portion of the metal deposition layer 35 corresponding to the exposure pattern is removed. To expose. As shown in FIG. 9, the exposed pattern of the metal deposition layer 35 includes a ring-shaped electrode portion 41, a coil 32 formed in a portion facing each of the circuit forming portions 33, 32 and a lead part 42 for connecting the P.32 with the P.32. Next, using the electrode portion 41 as one electrode, the exposed portion of the metal deposition layer 35 is subjected to electroplating or precision electroforming, and as shown in FIG. 36 are laminated. Next, the photoresist layer 38 adhered to the surface of the completed wafer 37 is removed by an ashing process or the like, and as shown in FIG. A completed wafer 37 on which the metal plating layer 36 having Next, the metal deposition layer 35 exposed from the metal plating layer 36 is selectively etched to remove the metal deposition layer 35 exposed from the metal plating layer 36, as shown in FIG. As a result, a completed wafer 37 is obtained in which both the metal deposition layer 35 and the metal plating layer 36 are formed in the required conductive patterns shown in FIG. Finally, the completed wafer 37 is scribed to obtain the required IC elements 30 shown in FIG.
[0056]
As described above, the pattern antenna 12b is arranged at the storage position corresponding to the cartridge 11 of the library device 10, and communication is performed between the coil-on-chip 21 formed on the cartridge 11 and the pattern antenna 12b. A voltage is applied by sequentially scanning from the unit 13 to each of the pattern antennas 12b. Thus, the pattern antenna 12b of the library device 10 and the coil-on-chip 21 of the cartridge 11 communicate with each other, and the identification information stored in the coil-on-chip 21 can be transmitted to the reader / writer unit 13. For this reason, it is possible to identify the cartridge 11 by applying a voltage to the pattern antenna 12b without searching the individual cartridges 11 by sequentially scanning the scanning unit as in the related art.
[0057]
Since the cartridge 11 is identified by sequentially scanning and applying a voltage to the pattern antenna 12b, the time for operating the conventional scanning unit can be reduced, and the cartridge 11 can be quickly moved by the electrical scanning. Can be identified. Therefore, the cartridge 11 can be efficiently identified by the library device 10, and a desired cartridge can be specified. Further, by providing a parallel processing circuit in the reader / writer unit 13, a voltage can be simultaneously applied to the pattern antenna 12b, and the reception operation of the pattern antenna 12b can be performed by parallel processing. Thereby, the identification information of a plurality of cartridges can be acquired at the same time, and the acquisition speed of the identification information can be dramatically improved.
[0058]
Further, by storing data and identification information for identifying the cartridge in the coil-on-chip 21, the antenna coil of the coil-on-chip 21 is small, so that the pattern antenna 12b of the antenna array 12 provided in the library device 10 is downsized. can do. Therefore, the interval between the pattern antennas 12b on the antenna array 12 can be reduced, and the arrangement pitch L, which is the interval between the cartridges 11, can be reduced. By reducing the arrangement pitch L, the storage efficiency of the cartridge 11 in the library device 10 can be improved. Further, since the antenna of the coil-on-chip 21 is small and the communication distance is limited, the antenna can be a fixed antenna and can be realized almost in close contact. Therefore, even if the arrangement pitch L is reduced, the cartridge 11 and the antenna array It is possible to reduce the collision (collision) of the communication between the adjacent radio waves transmitted and received between the radio waves. The arrangement pitch L can theoretically be substantially the same as the thickness of the cartridge.
[0059]
Furthermore, since the cartridge 11 can be identified without using a scan unit, wiring of the scan unit can be omitted, and a simple data library device can be realized. Further, since the drive system can be scanned only by the robot arm 14 without the scan unit, the operation of the cartridge 11 can be controlled in the shortest time based on the identification information by electrical scanning. Since the cartridge 11 can be identified by electrical scanning using only the robot arm 14, troubles such as disconnection due to mechanical stress can be avoided.
[0060]
【The invention's effect】
According to the present invention, it is possible to provide a data library recognizing device, a data library recognizing method, and a data library recognizing system capable of efficiently recognizing a storage position in a library of a cartridge having a recording medium capable of storing data. it can.
[Brief description of the drawings]
FIG. 1 is a schematic diagram showing a data library recognition system according to an embodiment of the present invention.
FIG. 2 is a schematic diagram showing an antenna array according to the embodiment of the present invention.
FIG. 3 is a schematic view showing a cartridge according to the embodiment of the present invention.
FIG. 4 is a schematic diagram showing a coil-on-chip according to an embodiment of the present invention.
FIG. 5 is a configuration diagram showing an IC element used in the embodiment of the present invention.
FIG. 6 is a sectional view showing an IC element used in the embodiment of the present invention.
FIG. 7 is a configuration diagram showing a completed wafer used in the embodiment of the present invention.
FIG. 8 is a process chart showing a method for manufacturing an IC element used in the embodiment of the present invention.
FIG. 9 is a configuration diagram showing a completed wafer used in the embodiment of the present invention.
FIG. 10 is a schematic diagram showing a data library in a conventional example.
FIG. 11 is a schematic view showing a cartridge in a conventional example.
FIG. 12 is a schematic diagram showing an RFID tag in a conventional example.
FIG. 13 is a schematic diagram showing a data scan unit in a conventional example.
FIG. 14 is a schematic diagram showing a data library in a conventional example.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 10 Library apparatus, 11 cartridge, 11a cartridge housing, 12 antenna array, 12a base material, 12b pattern antenna, 13 reader / writer unit, 14 robot arm, 21 coil on chip, 22 mini mold, 30 IC element, 30a input / output terminal , 31 surface protective film, 32 coil, 33 circuit forming section, 35 metal deposition layer, 36 metal plating layer, 37 completed wafer, 38 photoresist layer, 39 mask, 40 light, 41 electrode section, 42 lead section, 101 library, 102 scan unit, 103 drive unit, 104 tape cartridge, 105 RFID tag, 106 robot arm, 107 reader / writer antenna, 108 data communication cable, 110 base material, 111 RFID chip, 112 Antenna coil

Claims (13)

A data library recognition device that recognizes a data storage position in a library that stores a cartridge having a recording medium capable of storing data,
A storage unit for storing the cartridge,
A plurality of receiving means provided corresponding to each of the storage positions of the cartridge, wirelessly receiving identification information transmitted from the cartridge and identifying the cartridge or data,
A data library recognizing device comprising: a recognizing unit that recognizes a storage position of the data based on the identification information received by the receiving unit. 2. The data library recognizing device according to claim 1, wherein the receiving unit has an antenna coil for receiving the radio wave, and the antenna coil is provided corresponding to a storage position of the cartridge. 2. The data library recognition device according to claim 1, wherein the identification information is received by sequentially scanning reception operations of the plurality of reception units. The recognizing means communicates the identification information with a moving means for removing the cartridge from the library or moving the cartridge for storage in the library, and controls an operation of the moving means based on the identification information. 3. The data library recognition device according to claim 1, wherein: A data library recognition method for recognizing a data storage position in a library that stores a cartridge having a recording medium capable of storing data,
A receiving step of receiving wireless information transmitted from the cartridge and including identification information for identifying the cartridge or data by a plurality of receiving units provided corresponding to the storage positions of the cartridge;
A recognition step of recognizing a storage position of the data based on the identification information received by the receiving means. 6. The data library recognition method according to claim 5, wherein the wireless information is received by sequentially scanning reception operations of the plurality of reception units. A data library recognition system, comprising: a cartridge for storing a recording medium capable of storing data; and a library for storing the cartridge, wherein the data library recognition system recognizes a storage position of data in the library.
The cartridge, identification information storage means for storing identification information for identifying the cartridge or data,
Transmitting means for transmitting the identification information wirelessly,
A storage unit that stores the cartridge,
A plurality of receiving means provided corresponding to each of the storage positions of the cartridge, transmitted from the cartridge, and wirelessly receiving the identification information,
A data library recognition system comprising: recognition means for recognizing a storage position of the data based on the identification information received by the reception means. The identification information storage means is an IC element for storing information for specifying the data including the identification information, and the transmission means is an antenna coil provided on the IC element for transmitting the information. 8. The data library recognition system according to claim 7, wherein: 8. The data library recognition system according to claim 7, wherein said receiving means has an antenna coil for receiving said wirelessly, and said antenna coil is provided corresponding to a storage position of said cartridge. 8. The data library recognition system according to claim 7, wherein the identification information is received by sequentially scanning reception operations of the plurality of reception units. The recognizing unit communicates the identification information with a moving unit that moves to remove the cartridge from the library or store the cartridge in the library, and controls an operation of the moving unit based on the identification information. 9. The data library recognition system according to claim 7, wherein: A data library recognizing method, comprising: a cartridge storing a recording medium capable of storing data; and a library storing the cartridge, and recognizing a storage position of data in the library.
A transmitting step in which the cartridge transmits a radio signal including identification information for identifying the cartridge or data to the library;
A receiving step in which the library is transmitted from the cartridge and the wireless information is received by a plurality of receiving units provided corresponding to the storage positions of the cartridge;
A recognition step of recognizing a storage position of the data based on the identification information received by the receiving means. 13. The data library recognition method according to claim 12, wherein the wireless information is received by sequentially scanning reception operations of the plurality of reception units.

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