A wireless ic device that is miniaturized, allows simple and low-cost mounting of a wireless ic, and eliminates the possibility of damage occurring to the wireless ic due to static electricity, and an electronic apparatus equipped with the wireless ic device, includes a wireless ic chip that processes transmission and reception signals, and a feeder circuit substrate that includes a resonant circuit having an inductance element. feeder electrodes are provided on a surface of the feeder circuit substrate and are electromagnetically coupled to the resonant circuit. The feeder electrodes and are electromagnetically coupled to radiation plates and provided for a printed wiring board. The wireless ic chip is activated by a signal received by the radiation plates and a response signal from the wireless ic chip is radiated outward from the radiation plates.
1. A wireless ic device comprising:
a wireless ic arranged to transmit and receive signals;
a feeder circuit substrate including a feeder circuit incorporating an inductance element connected to the wireless ic in a galvanically conductive state and in which a feeder electrode coupled to the inductance element is provided on a surface of the feeder circuit substrate or an inside of the feeder circuit substrate;
a radiation plate that is electromagnetically coupled to the feeder electrode; and
a mounting electrode provided on a surface of the feeder circuit substrate; wherein
the mounting electrode is electrically independent from the feeder circuit.
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the feeder circuit substrate includes the inductance element and a capacitance element at different positions in plan view,
the capacitance element is electromagnetically coupled to a feeder electrode that is different from the feeder electrode to which the inductance element is electromagnetically coupled, and
the different radiation plates are respectively coupled to the feeder electrodes in a galvanically non-conductive state.
23. The wireless ic device according to
24. The wireless ic device according to
25. The wireless ic device according to
27. An electronic apparatus comprising the wireless ic device according to
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1. Field of the Invention
The present invention relates to a wireless IC device and, more particularly, to a wireless IC device that has a wireless IC used in an RFID (Radio Frequency Identification) system, and an electronic apparatus.
2. Description of the Related Art
In recent years, an RFID system has been developed as an article management system, which includes a reader/writer that generates an induction field and an IC chip (also referred to as IC tag or wireless IC chip) that stores predetermined information allocated to an article or a casing, and non-contact communication is established between the reader/writer and the IC chip to transmit the information therebetween.
A known existing wireless IC device equipped with an IC chip includes a wireless IC tag as described in Japanese Unexamined Patent Application Publication No. 2005-244778. In the wireless IC tag, a dipole antenna (formed of a pair of main antenna elements and matching sections) is provided on a dielectric substrate, and a tag IC is electrically connected to an end portion of the dipole antenna. The matching section is arranged between the tag IC and each main antenna element and has the function of matching impedance therebetween.
However, the above wireless IC tag has the following problems. First, because each matching section and the corresponding main antenna element are formed adjacent to each other on a single substrate, the size of the wireless IC tag increases. Second, it is necessary to mount a small wireless IC chip on an electrode formed on a large substrate on which the main antenna elements and the matching sections are arranged, so a highly accurate mounter is required. In addition, it requires time for positioning at the time of mounting, so manufacturing time is increased, and cost for the wireless IC tag increases. Third, because the main antenna elements and the wireless IC chip are connected in an electrically conductive state, so there is a possibility that the wireless IC chip may be damaged when static electricity enters from the main antenna elements.
In addition, Japanese Unexamined Patent Application Publication No. 2000-311226 describes a wireless IC card. The wireless IC card uses an IC chip in which an antenna coil is formed on the surface of the IC chip. In the above wireless IC card, a first antenna coil formed on the IC chip is coupled to a second antenna coil formed on a module substrate through a magnetic field.
However, in the wireless IC card described in Japanese Unexamined Patent Application Publication No. 2000-311226, it is necessary to accurately control the interval between the first and second antenna coils to a size at which a desired coupling is achieved. Specifically, as described in the paragraph [0107] of Japanese Unexamined Patent Application Publication No. 2000-311226, it is necessary to set the interval to a smaller interval that is smaller than or equal to 20 μm. When the two antenna coils are coupled with the above small interval, there is a problem that slight variations in the amount or dielectric constant of insulating adhesive arranged between the two antenna coils and in between each antenna coil vary a coupled state and, therefore, the radiation characteristic of the wireless IC card decreases. In addition, in order to mount the IC chip on the module substrate at a small interval with high accuracy, it requires an expensive mounter, and, as a result, cost for the wireless IC card increases.
In view of the above, preferred embodiments of the present invention provide a wireless IC device that can achieve miniaturization, allows simple and low-cost mounting of a wireless IC, and eliminates the possibility of any damage occurring to the wireless IC due to static electricity, and provide an electronic apparatus equipped including such a novel wireless IC device.
In addition, preferred embodiments of the present invention provide a wireless IC device that achieves the advantages of the preferred embodiments described in the preceding paragraph and is able to withstand against an impact due to a drop, or the like, and a stress due to heat shrinkage, and to provide an electronic apparatus including the novel IC device.
A wireless IC device according to a preferred embodiment of the present invention includes: a wireless IC that processes transmission and reception signals; a feeder circuit substrate including a feeder circuit incorporating an inductance element connected to the wireless IC in a galvanically conductive state and in which a feeder electrode coupled to the inductance element is provided on a surface of the substrate or an inside of the substrate; and a radiation plate that is electromagnetically coupled to the feeder electrode.
In the above wireless IC device, the feeder electrode provided on the surface or inside of the feeder circuit substrate is coupled to the inductance element provided for the feeder circuit substrate and is electromagnetically coupled to the radiation plate that functions as an antenna. It is not necessary that the feeder circuit substrate is equipped with a radiation plate having a relatively large size. Thus, the feeder circuit substrate may be exceedingly miniaturized. It is only necessary that the wireless IC is mounted on the above small feeder circuit substrate. An IC mounter, or the like, used widely in the existing art may be used, so mounting cost reduces. In addition, when the wireless IC is changed in response to the frequency used in an RFID system, it is only necessary to change the design of a resonant circuit and/or matching circuit of the feeder circuit substrate, and it is not necessary to change the shape or size of the radiation plate. In terms of this point as well, it is possible to achieve low cost.
Particularly, one of the unique features of the wireless IC device according to the present preferred embodiment is that the feeder electrode is provided for the feeder circuit substrate, and the feeder electrode is coupled to the inductance element and is electromagnetically coupled to the radiation plate. The inductance element is in a galvanically conductive state with the wireless IC; and, when the radiation plate and the feeder electrode are in a galvanically non-conductive state, it is possible to prevent any damage occurring to the wireless IC due to static electricity that enters from the radiation plate.
Note that the wireless IC may be in chip form, and the wireless IC may be able to rewrite information or may have an information processing function other than the RFID system in addition to storing various pieces of information regarding an article to which the wireless IC device is attached.
Another preferred embodiment of the present invention provides an electronic apparatus that includes the above wireless IC device. The radiation plate is provided for a printed wiring board incorporated in an apparatus casing, and the feeder electrode provided for the feeder circuit substrate is electromagnetically coupled to the radiation plate.
According to various preferred embodiments of the present invention, it is not necessary that the feeder circuit substrate is equipped with a radiation plate having a relatively large size, so the feeder circuit substrate may be exceedingly miniaturized. Therefore, a small wireless IC may also be easily mounted using an existing mounter. Thus, mounting cost reduces. To change a frequency band used, it is only necessary to change the design of the resonant circuit. In addition, the feeder electrode provided for the feeder circuit substrate is electromagnetically coupled to the radiation plate. This eliminates the possibility that the wireless IC is damaged because of static electricity that enters from the radiation plate. In addition, because the radiation plate does not sustain any damage due to a bonding material, such as solder, mechanical reliability is greatly improved.
In addition, by providing the mounting electrode on the surface of the feeder circuit substrate separately from the feeder electrode, the bonding strength of the feeder circuit substrate is greatly improved. Thus, even when the wireless IC device receives an impact because of a drop, or the like, or when thermal stress is applied to the radiation substrate or the feeder circuit substrate, it does not adversely influence electromagnetic coupling between the feeder electrode and the radiation plate.
Particularly, the mounting electrode provided on the side surface of the feeder circuit substrate is fixed to a mounting land different from the radiation plate. Thus, the feeder circuit substrate and the radiation plate are desirably coupled to each other through a simple manufacturing process without variations in gap therebetween, and variations in degree of coupling are substantially eliminated.
Other features, elements, arrangements, steps, characteristics and advantages of the present invention will become more apparent from the following detailed description of preferred embodiments of the present invention with reference to the attached drawings.
Hereinafter, preferred embodiments of a wireless IC device and an electronic apparatus according to the present invention will be described with reference to the accompanying drawings. Note that in the drawings, like reference numerals denote like components or portions, and the overlap description is omitted.
The wireless IC chip 5 preferably includes a clock circuit, a logic circuit, a memory circuit, and the like. The wireless IC chip 5 stores necessary information. As shown in
In addition, a protection film 9 is arranged on the surface of the feeder circuit substrate 10 so as to cover a portion connecting with the wireless IC chip 5 in order to improve the bonding strength between the wireless IC chip 5 and the feeder circuit substrate 10.
The radiation plates 21a and 21b are arranged so that an electrode film formed of a conductive paste or metal plating such as Al, Cu and Ag is provided in a predetermined shape in the radiation substrate 20 having a multilayer structure. Electrodes 26a and 26b are provided on the surface of the radiation substrate 20. Note that the radiation substrate 20 is not limited to a printed wiring board made of glass epoxy resin but it may be formed of a resin substrate, made of another resin, or a ceramic substrate.
The feeder circuit substrate 10 incorporates a resonant circuit (not shown in
The feeder circuit substrate 10 incorporates the resonant circuit having a predetermined resonant frequency. The feeder circuit substrate 10 transmits a transmission signal having a predetermined frequency, output from the wireless IC chip 5, to the radiation plates 21a and 21b via the feeder electrodes 19a and 19b, or the like, and selects a reception signal having a predetermined frequency among signals received by the radiation plates 21a and 21b and then supplies the reception signal to the wireless IC chip 5. Therefore, in the wireless IC device 1, the wireless IC chip 5 is activated by a signal received by the radiation plates 21a and 21b, and a response signal from the wireless IC chip 5 is radiated outward from the radiation plates 21a and 21b.
In the wireless IC device 1, the feeder electrodes 19a and 19b provided on the surface of the feeder circuit substrate 10 are coupled to the resonant circuit incorporated in the substrate 10, and are coupled to the radiation plates 21a and 21b, which function as an antenna, in an electrically non-conductive state. It is not necessary that the feeder circuit substrate 10 is equipped with the radiation plates 21a and 21b having a relatively large size. Thus, the feeder circuit substrate 10 may be exceedingly miniaturized. The wireless IC chip 5 may be mounted on the above small feeder circuit substrate 10. A mounter, or the like, used widely in the existing art may be used, so mounting cost is greatly reduced. In addition, to change a frequency band used, it is only necessary to change the design of the resonant circuit, and the radiation plates 21a and 21b, and the like, may be used without any change. In addition, the radiation plates 21a and 21b are in an electrically non-conductive state with the feeder electrodes 19a and 19b. Thus, static electricity that enters from the radiation plates 21a and 21b is not applied to the wireless IC chip 5. This prevents any damage occurring to the wireless IC chip 5 due to static electricity.
In the fifth preferred embodiment, the radiation plates 21a and 21b are mainly capacitively coupled to the electrodes 26c and 26d, and the electrodes 26a and 26b are respectively connected to the electrodes 26c and 26d through the via hole conductors 27 and are electrically connected to the feeder electrodes 19a and 19b through the conductive adhesive 22. Thus, the operations and advantages of the fifth preferred embodiment are similar to those of the first preferred embodiment.
In the tenth preferred embodiment, the mounted electronic circuit components, for example, include a chip resistor 72 and a wireless communication circuit 73 on which IC components are mounted. Note that in the first to tenth preferred embodiments, the radiation plates 21a and 21b may be disposed on the back surface of the radiation substrate 20.
A first example of a resonant circuit incorporated in the feeder circuit substrate 10 is shown as an exploded perspective view of the feeder circuit substrate 10 in
As shown in
By laminating the sheets 11A to 11H, an inductance element L1 is defined by the conductor patterns 16a that are spirally connected through the via hole conductors 14c, 14d and 14g, an inductance element L2 is defined by the conductor patterns 16b that are spirally connected through the via hole conductors 14b, 14e and 14f, a capacitance element C1 is defined by the capacitor electrodes 18a and 18b, and a capacitance element C2 is defined by the capacitor electrodes 18b and 17.
One end of the inductance element L1 is connected to the capacitor electrode 18b through the via hole conductors 14c and 13d, the conductor pattern 15a and the via hole conductor 13c. One end of the inductance element L2 is connected to the capacitor electrode 17 through the via hole conductor 14a. In addition, the other ends of the inductance elements L1 and L2 are integrated in the sheet 11H, and connected to the connecting electrode 12a through the via hole conductor 13e, the conductor pattern 15b and the via hole conductor 13a. Furthermore, the capacitor electrode 18a is electrically connected to the connecting electrode 12b through the via hole conductor 13b.
Then, the connecting electrodes 12a and 12b are electrically connected to the terminal electrodes 6 (see
In addition, the feeder electrodes 19a and 19b are provided on the back surface of the feeder circuit substrate 10, for example, by applying conductive paste. The feeder electrode 19a is electromagnetically coupled to the inductance elements L (L1 and L2). The feeder electrode 19b is electrically connected to the capacitor electrode 18b through the via hole conductor 13f. The feeder electrodes 19a and 19b are coupled to the radiation plates 21a and 21b in an electrically non-conductive state, as described above. The equivalent circuit of the above described resonant circuit is shown in
Note that in the resonant circuit, the inductance elements L1 and L2 are structured so that the two conductor patterns 16a and 16b are arranged in parallel or substantially parallel with each other. The two conductor patterns 16a and 16b have different line lengths, so different resonant frequencies may be set for the two conductor patterns 16a and 16b. Thus, the wireless IC device 1 may have a wide band.
Note that the ceramic sheets 11A to 11H may be made of a magnetic ceramic material, and the feeder circuit substrate 10 may be easily obtained by a process of manufacturing a multilayer substrate, such as sheet lamination and thick film printing, used in the existing art.
In addition, it is also possible that the sheets 11A to 11H are formed as a flexible sheet made of a dielectric material, such as polyimide and liquid crystal polymer, electrodes and conductors are formed on the sheets by thick film forming, or the like, those sheets are laminated and thermally bonded to form a laminated body, and the inductance elements L1 and L2 and the capacitance elements C1 and C2 are incorporated in the laminated body.
In the feeder circuit substrate 10, the inductance elements L1 and L2 and the capacitance elements C1 and C2 are provided at different positions in plan view. The feeder circuit substrate 10 is electromagnetically coupled to the feeder electrode 19a (radiation plate 21a) by the inductance elements L1 and L2. The feeder circuit substrate 10 is capacitively coupled to the radiation plate 21b by the capacitance element C1.
Thus, the wireless IC device 1, in which the wireless IC chip 5 is mounted on the feeder circuit substrate 10, receives a high-frequency signal (for example, UHF frequency band) radiated from a reader/writer (not shown) by the radiation plates 21a and 21b, resonates the resonant circuit that is magnetically and electrically coupled to the feeder electrodes 19a and 19b, and supplies only a reception signal of a predetermined frequency band to the wireless IC chip 5. On the other hand, the wireless IC device 1 extracts predetermined energy from the reception signal, and matches information stored in the wireless IC chip 5 with a predetermined frequency in the resonant circuit using the predetermined energy as a driving source. After that, the wireless IC device 1 transmits the information to the radiation plates 21a and 21b through the feeder electrodes 19a and 19b, and then transmits and transfers the information from the radiation plates 21a and 21b to the reader/writer.
In the feeder circuit substrate 10, a resonant frequency characteristic is determined by the resonant circuit formed of the inductance elements L1 and L2 and the capacitance elements C1 and C2. The resonant frequency of a signal radiated from the radiation plates 21a and 21b is substantially determined by the self resonance frequency of the resonant circuit. Note that the circuit in the feeder circuit substrate 10 is preferably designed so that the imaginary portion of an input/output impedance of the wireless IC chip 5 conjugates with the imaginary portion of an impedance when viewed from the connecting electrodes 12a and 12b on the feeder circuit substrate 10 toward the feeder electrodes 19a and 19b, thus making it possible to efficiently transmit and receive signals.
Incidentally, the resonant circuit also serves as a matching circuit for matching the impedance of the wireless IC chip 5 with the impedance of the radiation plates 21a and 21b. The feeder circuit substrate 10 may include a matching circuit that is provided separately from the resonant circuit including the inductance element and the capacitance element (in this sense, the resonant circuit is also referred to as a matching circuit). If the function of a matching circuit is added to the resonant circuit, the design of the resonant circuit tends to be complex. When a matching circuit is provided separately from the resonant circuit, it is possible to design the resonant circuit and the matching circuit separately.
In addition, the feeder circuit substrate 10 may include only a matching circuit. Furthermore, the circuit in the feeder circuit substrate 10 may include only an inductance element. In this case, the inductance element has the function of matching the impedance between the radiation plates 21a and 21b and the wireless IC chip 5.
In addition, as described in the eighth and ninth preferred embodiments, some of the elements that constitute the resonant circuit may be mounted on the substrate 10 or the substrate 20.
A second example of a resonant circuit incorporated in a feeder circuit substrate 30 is shown as an exploded perspective view of the feeder circuit substrate 30 in
As shown in
By laminating the above sheets 31A to 31E, an inductance element L includes the conductor patterns 36 that are spirally connected by the via hole conductors 33c. In addition, a capacitance element C is defined by the line capacity of the conductor patterns 36. One end of the inductance element L is connected to the connecting electrode 12a through the via hole conductor 33a.
In addition, the feeder electrode 19 is provided on the back surface of the feeder circuit substrate 30 by, for example, applying conductive paste. The feeder electrode 19 is connected to the other end of the inductance element L through the via hole conductor 33e, and is connected to the connecting electrode 12b through the via hole conductors 33d and 33b. The feeder electrode 19 is coupled to the radiation plate 21 in an electrically non-conductive state. The equivalent circuit of the above described resonant circuit is shown in
The resonant circuit is constructed so that the wireless IC chip 5 is galvanically connected to the feeder electrode 19, and supplies a high-frequency signal received by the radiation plate 21 to the wireless IC chip 5. On the other hand, information stored in the wireless IC chip 5 is transmitted to the feeder electrode 19 and the radiation plate through the resonant circuit to transmit and transfer the information from the radiation plate 21 to a reader/writer.
Next, a cellular phone, which is one preferred embodiment of an electronic apparatus according to the present invention, will be described. A cellular phone 50 shown in
As shown in
The wireless IC device 1 mounted on the printed wiring board 55 may be the one shown in
A ground pattern 56 indicated by oblique lines in
Specifically, in the nineteenth preferred embodiment, the feeder electrodes 19a and 19b are incorporated in the feeder circuit substrate 10, and are electromagnetically coupled to coupling portions 21a′ and 21b′, which are one end portions of the radiation plates 21a and 21b arranged to have a meander shape, in an electrically non-conductive state. The mounting electrodes 18a and 18b are disposed on the back surface of the feeder circuit substrate 10, and mounted electrodes 24a and 24b are disposed on the radiation substrate 20. The mounting electrodes 18a and 18b and the mounted electrodes 24a and 24b are respectively connected by a conductive material (which may be electrically insulating adhesive) such as solder 41.
The other configuration is similar to that of the first preferred embodiment. The basic operations and advantages as the wireless IC device are similar to those of the first preferred embodiment. In addition, in the nineteenth preferred embodiment, the mounting electrodes 18a and 18b are provided on the back surface of the feeder circuit substrate 10 and are connected to the mounted electrodes 24a and 24b provided on the radiation substrate 20. Thus, the bonding strength between the feeder circuit substrate 10 and the radiation substrate 20 improves. In addition, even when the wireless IC device receives an impact due to a drop, or the like, or even when the radiation substrate 20 or the feeder circuit substrate 10 thermally contracts to generate thermal stress, electromagnetic coupling between the feeder electrodes 19a and 19b and the radiation plates 21a and 21b is not adversely influenced.
The other configuration is similar to that of the first preferred embodiment. The basic operations and advantages as the wireless IC device are similar to those of the first preferred embodiment. The operations and advantages when provided with the mounting electrode are similar to those of the nineteenth preferred embodiment. In addition, the mounting electrode is preferably located in the middle portion, so it is possible to extend the radiation plates 21a and 21b from a side in the longitudinal direction of the feeder circuit substrate 10. In addition, stress applied to a protruding portion reduces against warpage, or the like, of the feeder circuit substrate 10.
The other configuration is similar to that of the first preferred embodiment. The basic operations and advantages as the wireless IC device are similar to those of the first preferred embodiment. The operations and advantages when provided with the mounting electrodes are those described in the nineteenth preferred embodiment.
The other configuration is similar to that of the first preferred embodiment. The basic operations and advantages as the wireless IC device are similar to those of the first preferred embodiment. The operations and advantages when provided with the mounting electrodes are those described in the nineteenth preferred embodiment. Particularly, in the twenty-second preferred embodiment, the mounting electrodes and the mounted electrodes 24a to 24d are provided at the outer edge portions of the feeder circuit substrate 10. This improves the accuracy of a position when the feeder circuit substrate 10 is mounted on the radiation substrate 20 using reflow solder. That is, this is because, during reflow soldering, self-alignment effect due to the surface tension of solder arises at each of the four electrodes 24a to 24d located at the outer edge portions.
The other configuration is similar to that of the first preferred embodiment. The basic operations and advantages as the wireless IC device are similar to those of the first preferred embodiment. The operations and advantages when provided with the mounting electrodes 18a to 18d are those described in the nineteenth preferred embodiment. Particularly, in the twenty-third preferred embodiment, the mounting electrodes 18a to 18d are provided on the side surfaces of the feeder circuit substrate 10, so there is a spatial room on the back surface of the substrate 10. Thus, by arranging the coupling portions 21a′ and 21b′, which are one end portions of the radiation plates 21a and 21b, substantially over the entire back surface, it is possible to improve a degree of coupling to which the feeder electrodes 19a and 19b are coupled to the radiation plates 21a and 21b.
The other configuration is similar to that of the first preferred embodiment. The basic operations and advantages as the wireless IC device are similar to those of the first preferred embodiment. The operations and advantages when provided with the mounting electrodes 18a and 18b are those described in the nineteenth preferred embodiment.
The other configuration is similar to that of the first preferred embodiment. The basic operations and advantages as the wireless IC device are similar to those of the first preferred embodiment. The operations and advantages when provided with the mounting electrodes 18a and 18b are those described in the nineteenth preferred embodiment.
The areas of the mounting electrodes 18a to 18d formed on the back surface of the feeder circuit substrate 10 are equal to those of the nineteenth and twenty-second preferred embodiments, and the amount of solder for bonding is supplied in accordance with the areas of the mounting electrodes 18a to 18d. Extra solder spreads over to the mounted electrodes 24a to 24d, so it is possible to reduce the thickness of solder, and it is possible to prevent variations in thickness of solder. By so doing, variations in gaps between the radiation plates 21a and 21b and the feeder electrodes 19a and 19b reduce, and the degree of coupling becomes stable. Then, it is desirable that Au plating, or the like, is applied to the mounted electrodes 24a to 24d to apply coating such that solder wets to spread over the mounting electrodes 24a to 24d.
In addition, as described in the twenty-fifth preferred embodiment, when the resist film 29 is formed on the radiation plates 21a and 21b, it is possible to determine a gap between the radiation plates 21a and 21b and the back surface of the feeder circuit substrate 10 based on the thickness of the resist film 29. A similar advantage to this may be achieved by forming a protrusion on the back surface of the feeder circuit substrate 10 using a conductive layer or a resin layer.
The other configuration is similar to that of the first preferred embodiment. The basic operations and advantages as the wireless IC device are similar to those of the first preferred embodiment. The operations and advantages when provided with the mounting electrodes 18a and 18b are those described in the nineteenth preferred embodiment. Particularly, in the twenty-eighth preferred embodiment, because the radiation plates 21a and 21b include the mounted electrodes 24a and 24b, the electrodes are easily formed, and the strength of the mounted electrodes 24a and 24b increases.
The other configuration is similar to that of the first preferred embodiment. The basic operations and advantages as the wireless IC device are similar to those of the first preferred embodiment. The operations and advantages when provided with the mounting electrode 18 are those described in the nineteenth preferred embodiment. Particularly, in the thirtieth preferred embodiment, the radiation plates 21a and 21b are magnetically coupled to the feeder circuit substrate 10, so the characteristic remains unchanged even when a position at which the feeder circuit substrate 10 is mounted slightly deviates or is deviated by rotating 180 degrees. In addition, a change in characteristic is small even when a resin material having a high dielectric constant is interposed between the feeder circuit substrate 10 and the radiation plates 21a and 21b.
As shown in
The feeder circuit substrate 120 includes a feeder circuit 121 having a resonant circuit/matching circuit that will be described below with reference to
The wireless IC chip 5 preferably includes a clock circuit, a logic circuit, a memory circuit, and the like. The wireless IC chip 5 stores necessary information. As shown in
A radiation plate 131 is preferably disposed on the surface of printed circuit board 130 and includes an electrode film made of a nonmagnetic metal material. One end portion 131a and the other end portion 131b each are arranged to face the lower surface of the feeder circuit substrate 120, and are electromagnetically coupled to the feeder circuit 121. The overall shape of the radiation plate 131 can be varied as desired, and may be, for example, a loop shape or a dipole shape. In addition, the radiation plate 131 may be provided inside the printed circuit board 130. Note that the printed circuit board 130 is incorporated in an article, such as a cellular phone.
Mounting electrodes 122 are preferably provided on two opposite side surfaces of the feeder circuit substrate 120 and are not electrically connected to the feeder circuit 121, which will be described in detail below. As shown in
In the soldering, first, solder paste 133 is applied to the lands 132 as indicated by the broken line in
When the solder paste 133 is in a molten state in the reflow furnace, the solder paste 133 contacts each mounting electrode 122, and the electromagnetic coupling module 100 is adhered onto the printed circuit board 130. After being taken out from the reflow furnace, the solder paste 133 contracts with a decrease in temperature, and hardens in a bridge shape between the lands 132 and the mounting electrodes 122 to generate internal stress in the arrow A direction. By so doing, the feeder circuit substrate 120 is pulled toward the printed circuit board 130, and the lower surface of the feeder circuit substrate 120 closely adheres to the end portions 131a and 131b of the radiation plate 131.
When considering in detail the above phenomenon at the time of soldering, the above phenomenon is due to a situation that the mounting electrodes 122 are provided on the side surfaces of the feeder circuit substrate 120 away from the lower surface (in other words, the mounting electrodes 122 are disposed only on the side surfaces and not disposed on the lower surface), and a gap g is present between each land 132 and the feeder circuit substrate 120. When the solder paste 133 at the gap g portion contracts at the time of hardening, stress in the arrow A direction occurs.
The feeder circuit substrate 120 directly adheres to the radiation plate 131 because of the stress due to contraction of the solder paste 133. Thus, the feeder circuit substrate 120 and the radiation plate 131 are desirably coupled to each other without variations in gap therebetween, and variations in degree of coupling are substantially eliminated. In addition, because the mounting electrodes 122 are not electrically connected to the feeder circuit 121 and are independent, corrosion of the mounting electrodes 122 due to solder, or the like, does not adversely influence the electrical characteristic and reliability of the electromagnetic coupling module 100.
In addition, the mounting electrodes 122 are disposed on the two opposite side surfaces of the feeder circuit substrate 120, so it is possible to mount the feeder circuit substrate 120 on the printed circuit board 130 with a further improved accuracy in a well balanced manner. Particularly, in the present preferred embodiment, because the mounting electrodes 122 are provided on the two opposite side surfaces of the feeder circuit substrate 120 at line-symmetrical positions, mounting accuracy and balance are further improved.
Moreover, it is only necessary to use a simple manufacturing process, that is, soldering by a reflow furnace, no expensive mounter is required. In addition, after the soldering, the electromagnetic coupling module 100 preferably is coated with a resin material to further improve the bonding strength of the electromagnetic coupling module 100 to the printed circuit board 130.
As shown in
The thirty-second preferred embodiment differs from the thirty-first preferred embodiment in that the mounting electrodes 122 are formed of via hole electrodes that are exposed on the side surfaces of the laminated body (feeder circuit substrate 120). In order to expose the via hole electrodes on the side surfaces of the laminated body, it is only necessary that the via hole electrodes are arranged along a cut line of a mother substrate when the feeder circuit substrate 120 is manufactured. A method of forming the above via hole electrodes (conductors) is described in Japanese Unexamined Patent Application Publication No. 2002-26513 in detail.
In the thirty-second preferred embodiment, bonding the mounting electrodes 122 and the lands 132 on the printed circuit board 130 by the solder paste 133 is similar to that of the thirty-first preferred embodiment, and the operations and advantages thereof are also similar.
Here, the first example of the feeder circuit substrate 120 will be described. As shown in an equivalent circuit in
The inductance elements L11 and L12 included in the feeder circuit 121 are magnetically coupled in opposite phases and resonate at a frequency processed by the wireless IC chip 5, and are electromagnetically coupled to the end portions 131a and 131b of the radiation plate 131. In addition, the feeder circuit 121 is electrically connected to the input/output terminal electrode 6 of the wireless IC chip 5 to match the impedance (for example, about 50Ω) of the wireless IC chip 5 with the impedance (spatial impedance of 377Ω, for example) of the radiation plate 131.
Thus, the feeder circuit 121 transmits a transmission signal having a predetermined frequency and output from the wireless IC chip 5 to the radiation plate 131, and selects a reception signal having a predetermined frequency from among signals received by the radiation plate 131 and then supplies the selected reception signal to the wireless IC chip 5. Thus, in the wireless IC device 1, the wireless IC chip 5 is activated by a signal received by the radiation plate 131, and a response signal from the wireless IC chip 5 is radiated outward from the radiation plate 131.
As described above, in the wireless IC device, the feeder circuit 121 provided for the feeder circuit substrate 120 sets a resonant frequency of a signal. Thus, even when the wireless IC device is attached to various types of articles, the wireless IC device operates without any change. Hence, variations in radiation characteristic are prevented, and it is not necessary to change the design of the radiation plate 131, or the like, for each individual article. Then, the frequency of the transmission signal radiated from the radiation plate 131 and the frequency of the reception signal supplied to the wireless IC chip 5 substantially equal to the resonant frequency of the feeder circuit 121 in the feeder circuit substrate 120. A maximum gain of a signal is substantially determined by at least any one of the size or shape of the feeder circuit 121, a distance or a medium between the feeder circuit 121 and the radiation plate 131. The frequencies of the transmission and reception signals are determined on the feeder circuit substrate 120. Thus, irrespective of the shape, size, arrangement, or the like, of the radiation plate 131, for example, even when the wireless IC device is rolled or held between dielectric materials, the frequency characteristic remains unchanged, and the stable frequency characteristic may be obtained.
Next, the configuration of the feeder circuit substrate 120 will be described with reference to
By laminating the above sheets 141a to 141i, the inductance element L11 in which the wiring electrodes 146a are spirally connected through the via hole conductors 147a, and the inductance element L12 in which the wiring electrodes 146b are spirally connected through the via hole conductors 147b, are formed. In addition, capacitances are formed between the lines of each of the wiring electrodes 146a and 146b.
An end portion 146a-1 of the wiring electrode 146a on the sheet 141b is connected to the feeder terminal electrode 142a through a via hole conductor 145a. An end portion 146a-2 of the wiring electrode 146a on the sheet 141h is connected to the feeder terminal electrode 142b through via hole conductors 148a and 145b. An end portion 146b-1 of the wiring electrode 146b on the sheet 141b is connected to the feeder terminal electrode 142b through a via hole conductor 144b. An end portion 146b-2 of the wiring electrode 146b on the sheet 141h is connected to the feeder terminal electrode 142a through via hole conductors 148b and 144a. Furthermore, end portions 146a-2 and 146b-2 of the wiring electrodes 146a and 146b are connected to the planar electrodes 149a and 149b through via hole conductors.
In the above described feeder circuit 121, the inductance elements L11 and L12 are respectively wound in opposite directions, so magnetic fields generated in the inductance elements L11 and L12 are cancelled. Because the magnetic fields are cancelled, it is necessary to extend the wiring electrodes 146a and 146b in order to obtain desired inductances. By so doing, because the Q value decreases, the steep resonant characteristic disappears, and a wide band is obtained around the resonant frequency.
The inductance elements L11 and L12 are located at left and right different positions when the feeder circuit substrate 120 is viewed in plan. In addition, magnetic fields generated in the inductance elements L11 and L12 are opposite in directions. By so doing, when the feeder circuit 121 is coupled to the end portions 131a and 131b of the loop radiation plate 131, electric currents in opposite directions are excited in the end portions 131a and 131b. Thus, it is possible to transmit and receive signals by the loop radiation plate 131. Note that the inductance elements L11 and L12 may be respectively coupled to two different radiation plates.
When the feeder circuit substrate 120 is made of a magnetic material, and the inductance elements L11 and L12 are provided in the magnetic material, it is possible to obtain large inductances, and it is possible to handle a frequency of approximately 13.56 MHz band, for example. In addition, even when variations in machining of the magnetic sheets or variations in permeability occur, it is possible to absorb variations in impedance with the wireless IC chip 5. The permeability μ of the magnetic material is desirably about 70.
In addition, because the two inductance elements L11 and L12 have different inductances, the feeder circuit 121 has a plurality of resonant frequencies to make it possible to widen the band of the wireless IC device. However, the inductances of the inductance elements L11 and L12 may be set at substantially the same value. In this case, it is possible to equalize the magnitudes of the magnetic fields generated in the inductance elements L11 and L12. By so doing, it is possible to equalize the amount by which the magnetic fields are cancelled in the two inductance elements L11 and L12, and a wide band is obtained around the resonant frequency.
Note that the feeder circuit substrate 120 include a multilayer substrate made of ceramics or resin or may be a substrate including laminated flexible sheets made of a dielectric material, such as polyimide and liquid crystal polymer. Particularly, the inductance elements L11 and L12 are incorporated in the feeder circuit substrate 120. Thus, the feeder circuit 121 is less likely to experience interference or influence from outside the substrate, and it is possible to prevent variations in radiation characteristic.
In addition, by providing the planar electrodes 149a and 149b between the inductance elements L11 and L12 and the radiation plate 131, it is possible to prevent variations in coupling between the feeder circuit 121 and the radiation plate 131. Note that the planar electrodes 149a and 149b need not be electrically connected to the wiring electrodes 146a and 146b, and the planar electrodes 149a and 149b are not necessary.
The second example of the feeder circuit substrate 120 includes an equivalent circuit shown in
By laminating the sheets 221a to 221h, the inductance element L11 in which the wiring electrodes 225a are spirally connected through the via hole conductors, and the inductance element L12 in which the wiring electrodes 225b are spirally connected through the via hole conductors, are formed. In addition, capacitances are formed between the lines of each of the wiring electrodes 225a and 225b.
The wiring electrodes 225a and 225b are integrated in a wiring electrode 225 on the sheet 221b. An end portion 225a′ of the wiring electrode 225a on the sheet 221g is connected to a feeder terminal electrode 222a through a via hole conductor. An end portion 225b′ of the wiring electrode 225b is connected to a feeder terminal electrode 222b through a via hole conductor.
The feeder circuit 121 that includes the thus configured inductance elements L11 and L12 is the equivalent circuit shown in
Thus, the operations and advantages of the second example are similar to those of the above first example. Particularly, by providing the planar electrodes 228a and 228b on the back surface of the feeder circuit substrate 120, it is possible to prevent variations in coupling between the feeder circuit 121 and the radiation plate 131. Note that the planar electrodes 228a and 228b are not necessary.
In a wireless IC device, it is desirable to provide a mounting electrode on a surface of a feeder circuit substrate. When the mounting electrode is provided separately from a feeder electrode and bonded onto a substrate of a radiation plate (for example, electrical connection by a conductive material, such as solder, or connection by an insulating material), the bonding strength improves. Thus, even when the wireless IC device receives an impact due to a drop, or the like, or when thermal stress is applied to the radiation substrate or the feeder circuit substrate, it does not adversely influence electromagnetic coupling between the feeder electrode and the radiation plate. Particularly, it is desirable to form the mounting electrode at an outer edge portion of the feeder circuit substrate. This makes it possible to improve the accuracy of a position at which the feeder circuit substrate is mounted. In addition, the mounting electrode may be disposed on a side surface of the feeder circuit substrate. When the mounting electrode is disposed on the side surface, there will be a spatial room on the back surface of the feeder circuit substrate. Thus, it is possible to utilize almost all the back surface for coupling with the radiation plate. This increases a degree of coupling between the feeder electrode and the radiation plate.
Particularly, by soldering the mounting electrode, which is provided on the side surface of the feeder circuit substrate, onto a mounting land on the substrate on which the radiation plate is provided, a lower surface of the feeder circuit substrate closely adheres to the radiation plate because of hardening contraction of solder. Thus, the feeder circuit substrate and the radiation plate are desirably coupled to each other without variations in gap therebetween, and variations in degree of coupling are substantially eliminated.
The mounting electrode is preferably disposed on each of two opposite side surfaces of the feeder circuit substrate. It is possible to mount the feeder circuit substrate on the substrate with a further improved accuracy in a well balanced manner. Because the mounting electrode is provided on each of the two opposite side surfaces of the feeder circuit substrate at a line-symmetrical position, mounting accuracy and balance are further greatly improved.
The mounting electrode may be located at a distance spaced away from the lower surface of the feeder circuit substrate. This prevents solder from spreading to the lower surface of the feeder circuit substrate. Thus, it is possible to ensure close contact between the feeder circuit substrate and the radiation plate.
The feeder circuit substrate preferably includes a laminated body in which an insulating material layer and an electrode layer are laminated, and the mounting electrode may be arranged so as to expose an electrode layer on at least one of the side surfaces of the laminated body. By forming the mounting electrode using the electrode layer that is partially exposed on the side surface of the laminated body, the mounting strength of the feeder circuit substrate improves.
In addition, the feeder circuit substrate preferably includes a laminated body in which an insulating material layer and an electrode layer are laminated, and the mounting electrode may be arranged in a recess that is formed on at least one of the side surfaces of the laminated body. By arranging solder in the recess, it is possible to prevent spreading of a solder fillet.
In addition, a resonant circuit and/or a matching circuit may be provided in the feeder circuit substrate. In addition, the radiation plate may be disposed on a surface and/or inside of the radiation substrate. In addition, the feeder electrode may be arranged over a range from a surface, facing the radiation plate, of the feeder circuit substrate to at least one of surfaces, not facing the radiation plate, of the feeder circuit substrate. The bonding strength of the feeder electrode improves. A plurality of the feeder electrodes or the mounting electrodes may be provided.
An inductance element and a capacitance element may be respectively provided on the feeder circuit substrate at different positions in plan view and are electromagnetically coupled to different feeder electrodes, and different radiation plates may be respectively coupled to the feeder electrodes. Because capacitive coupling is higher in efficiency of exchanging signal energy than magnetic coupling, it is possible to improve the radiation characteristic. In addition, a coupled state to the feeder electrode may be set separately between the inductance element and the capacitance element, so the degree of freedom for designing the radiation characteristic improves.
In addition, the resonant circuit or the matching circuit may be configured so that the wireless IC is galvanically connected to the feeder electrode. In addition, the resonant circuit or the matching circuit may include an element incorporated in the feeder circuit substrate and an element mounted on the feeder circuit substrate or an element mounted on a substrate on which the radiation plate is provided. When a chip inductor having a large inductance or a chip capacitor having a large capacitance is mounted on the feeder circuit substrate or the radiation substrate, the element incorporated in the feeder circuit substrate may have a small inductance or capacitance. Thus, it is possible to further reduce the size of the feeder circuit substrate.
The feeder circuit desirably includes at least two inductance elements having different inductances. Because of the different inductances, the feeder circuit may have a plurality of resonant frequencies to widen the band of the wireless IC device. Thus, it is possible to use the wireless IC device in all the countries of the world without any change in design.
It is desirable that the feeder circuit is electromagnetically coupled to the radiation plate, and the resonant frequency of a signal radiated from the radiation plate is substantially equal to the self-resonant frequency of the feeder circuit. Because the frequency of a signal is determined by the feeder circuit, so the length or shape of the radiation plate is selectable, and the degree of freedom for designing the radiation plate improves. In addition, irrespective of the shape, size, arrangement, or the like, of the radiation plate, for example, even when the wireless IC device is rolled or held between dielectric materials, the frequency characteristic remains unchanged, and the stable frequency characteristic may be obtained. In addition, even when the wireless IC device is attached to various types of articles, the wireless IC device operates without any change. Hence, variations in radiation characteristic are prevented, and it is not necessary to change the design of the radiation plate, or the like, for each individual article.
It is desirable that no electrode is provided on the lower surface of the feeder circuit substrate. This prevents solder from spreading to the lower surface of the feeder circuit substrate. Thus, it is possible to reliably ensure close contact between the feeder circuit substrate and the radiation plate.
The feeder circuit substrate may include a multilayer substrate made of ceramics or liquid crystal polymer. When the feeder circuit substrate is defined by a multilayer substrate, it is possible to highly accurately incorporate the inductance element or the capacitance element, and a degree of freedom for forming wiring electrodes is greatly improved.
In addition, it is desirable that a sealing resin is provided between the radiation substrate and the feeder circuit substrate or a protection film that covers at least one of the wireless IC chip, the feeder circuit substrate and the radiation plate is provided. The environmental resistance is greatly improved.
In addition, it is desirable that the imaginary portion of an input/output impedance of the wireless IC conjugates with the imaginary portion of an impedance when viewed from a portion of the feeder circuit substrate, connected to the wireless IC, toward the feeder electrode within or near a range of frequency used.
Note that the wireless IC device and the electronic apparatus according to the present invention are not limited to the above preferred embodiments; they may be modified into various forms within the scope of the present invention.
For example, the resonant circuit may have various configurations, elements and arrangements. In addition, the materials of the various electrodes and feeder circuit substrate described in the preferred embodiments are only illustrative, and a selected material may be used as long as the material has a necessary property. In addition, to mount the wireless IC chip on the feeder circuit substrate, a process other than the metal bump may be used. It is applicable that the wireless IC is not of a chip type but the wireless IC is disposed on the feeder circuit substrate. Furthermore, to fix the mounting electrode of the feeder circuit substrate to the mounting land, adhesive that hardens to contract may be used instead of solder, for example.
In addition, the electronic apparatus equipped with the wireless IC device according to the present invention is not limited to a cellular phone but it may be various wireless communication devices or household electrical appliances, such as a television and a refrigerator.
As described above, the present invention is useful for a wireless IC device and an electronic apparatus, and is particularly advantageous in that it is possible to achieve miniaturization, allows simple and low-cost mounting of a wireless IC, and eliminates the possibility of any damage from occurring to the wireless IC due to static electricity.
While preferred embodiments of the present invention have been described above, it is to be understood that variations and modifications will be apparent to those skilled in the art without departing the scope and spirit of the present invention. The scope of the present invention, therefore, is to be determined solely by the following claims.
Ishino, Satoshi, Kato, Noboru, Ikemoto, Nobuo, Dokai, Yuya, Kimura, Ikuhei, Kataya, Takeshi, Tanaka, Mikiko
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