WO2014132519A1 - アンテナ、プリント基板、及び無線通信装置 - Google Patents
アンテナ、プリント基板、及び無線通信装置 Download PDFInfo
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- WO2014132519A1 WO2014132519A1 PCT/JP2013/082821 JP2013082821W WO2014132519A1 WO 2014132519 A1 WO2014132519 A1 WO 2014132519A1 JP 2013082821 W JP2013082821 W JP 2013082821W WO 2014132519 A1 WO2014132519 A1 WO 2014132519A1
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- radiating element
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- branch portion
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01Q—ANTENNAS, i.e. RADIO AERIALS
- H01Q1/00—Details of, or arrangements associated with, antennas
- H01Q1/36—Structural form of radiating elements, e.g. cone, spiral, umbrella; Particular materials used therewith
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01Q—ANTENNAS, i.e. RADIO AERIALS
- H01Q1/00—Details of, or arrangements associated with, antennas
- H01Q1/12—Supports; Mounting means
- H01Q1/22—Supports; Mounting means by structural association with other equipment or articles
- H01Q1/24—Supports; Mounting means by structural association with other equipment or articles with receiving set
- H01Q1/241—Supports; Mounting means by structural association with other equipment or articles with receiving set used in mobile communications, e.g. GSM
- H01Q1/242—Supports; Mounting means by structural association with other equipment or articles with receiving set used in mobile communications, e.g. GSM specially adapted for hand-held use
- H01Q1/243—Supports; Mounting means by structural association with other equipment or articles with receiving set used in mobile communications, e.g. GSM specially adapted for hand-held use with built-in antennas
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01Q—ANTENNAS, i.e. RADIO AERIALS
- H01Q9/00—Electrically-short antennas having dimensions not more than twice the operating wavelength and consisting of conductive active radiating elements
- H01Q9/04—Resonant antennas
- H01Q9/16—Resonant antennas with feed intermediate between the extremities of the antenna, e.g. centre-fed dipole
- H01Q9/28—Conical, cylindrical, cage, strip, gauze, or like elements having an extended radiating surface; Elements comprising two conical surfaces having collinear axes and adjacent apices and fed by two-conductor transmission lines
- H01Q9/285—Planar dipole
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04B—TRANSMISSION
- H04B1/00—Details of transmission systems, not covered by a single one of groups H04B3/00 - H04B13/00; Details of transmission systems not characterised by the medium used for transmission
- H04B1/38—Transceivers, i.e. devices in which transmitter and receiver form a structural unit and in which at least one part is used for functions of transmitting and receiving
- H04B1/40—Circuits
Definitions
- the present invention relates to a small antenna, a printed board having the antenna, and a wireless communication device.
- a small-sized wireless communication device uses a dipole antenna, a monopole antenna, or an inverted L antenna that is a modification thereof, which has a small directivity and can radiate radio waves in a wide direction.
- these antennas in principle, require a size of about 1/2 to 1/4 of the wavelength, and thus it has been difficult to reduce the size.
- a matching circuit is required for impedance matching between the antenna and the feeder line, there is a problem in that the manufacturing cost increases.
- Patent Document 1 discloses a technique for miniaturizing an antenna by adding a parasitic element, a part of which is made of a magnetic material, to a dipole antenna.
- the technique described in Patent Document 1 enables the miniaturization and impedance matching of an antenna without using a matching circuit by controlling the distribution of magnetic lines of force in the vicinity of the antenna using a magnetic material.
- Non-Patent Document 1 discloses a technique for increasing the effective magnetic permeability by disposing a resonator structure called a split ring resonator in the vicinity of a monopole antenna and reducing the size of the monopole antenna. Yes.
- Low-cost antennas are often formed with a copper foil pattern formed on a printed circuit board. Since the antenna disclosed in Patent Document 1 needs to use a magnetic material, it cannot be manufactured by a general manufacturing process of a printed circuit board, and there is a problem that manufacturing cost increases. In addition, the antenna disclosed in Non-Patent Document 1 requires a split ring resonator provided separately from the monopole antenna to be disposed perpendicular to the ground plane. The split ring resonator disposed perpendicular to the ground plane cannot be manufactured integrally with the ground plane by a normal printed circuit board manufacturing process. For this reason, there exists a problem which manufacturing cost increases.
- An object of the present invention is to provide an antenna that is small in size and can be manufactured at low cost, and a printed circuit board and a wireless communication apparatus including the antenna.
- An antenna feed point comprising a first terminal and a second terminal; A conductive first radiating element connected to the first terminal; A conductive second radiating element connected to the second terminal; A conductive first branch portion having one end connected to a position other than the end of the first radiating element; A conductive second branch portion having one end connected to a position other than the end of the second radiating element; A conductive connecting element connecting a part of the first radiating element and a part of the second radiating element; The other end of the first branch portion and the other end of the second branch portion are opposed to each other to form a capacitor portion, The capacitor portion is located outside a region surrounded by the connection element, the first radiating element, and the second radiating element, A part of the first radiating element, a part of the second radiating element, the first branching part, the second branching part, and the capacitive part form a split ring resonator.
- An antenna is provided.
- An antenna feed point comprising a first terminal and a second terminal; A conductive first radiating element connected to the first terminal; A conductive second radiating element connected to the second terminal; A conductive first branch portion having one end connected to a position other than the end of the first radiating element; A conductive second branch portion having one end connected to a position other than the end of the second radiating element; A conductive connecting element connecting a part of the first radiating element and a part of the second radiating element; The other end of the first branch portion and the other end of the second branch portion are opposed to each other to form a capacitor portion, The capacitor portion is located outside a region surrounded by the connection element, the first radiating element, and the second radiating element, An antenna in which a part of the first radiating element, a part of the second radiating element, the first branch part, the second branch part, and the capacitor part form a split ring resonator.
- a printed circuit board comprising at least one of the above is provided.
- An antenna feed point comprising a first terminal and a second terminal; A conductive first radiating element connected to the first terminal; A conductive second radiating element connected to the second terminal; A conductive first branch portion having one end connected to a position other than the end of the first radiating element; A conductive second branch portion having one end connected to a position other than the end of the second radiating element; A conductive connecting element connecting a part of the first radiating element and a part of the second radiating element; The other end of the first branch portion and the other end of the second branch portion are opposed to each other to form a capacitor portion, The capacitor portion is located outside a region surrounded by the connection element, the first radiating element, and the second radiating element, An antenna in which a part of the first radiating element, a part of the second radiating element, the first branch part, the second branch part, and the capacitor part form a split ring resonator. Is provided.
- the present invention it is possible to provide a small antenna that can be manufactured at a low cost, and a printed circuit board and a wireless communication device including the antenna.
- FIG. 1 is a top view showing the configuration of the antenna 10 according to the first embodiment.
- 2 is a cross-sectional view of the antenna 10 taken along the dotted line A in FIG.
- the antenna 10 according to the first embodiment is formed on the surface layer of the printed circuit board 1 and includes an antenna feeding point 2, a first radiating element 3, and a second radiating element 4.
- the antenna feeding point 2 includes two terminals (+ terminal and ⁇ terminal).
- the first radiating element 3 is a linear conductor pattern connected to the + terminal of the antenna feeding point 2.
- the second radiating element 4 is a linear conductor pattern connected to the negative terminal of the antenna feeding point 2.
- the antenna feeding point 2 is connected to a transmission line that transmits a radio signal from a radio circuit (not shown), and can input a radio signal from the radio circuit to the antenna 10.
- the antenna 10 includes a first branch part 5a and a second branch part 5b, which are conductor patterns.
- One end of the first branch portion 5 a is connected to a position that is not an end portion of the first radiating element 3, and one end of the second branch portion 5 b is connected to a position that is not the end portion of the second radiating element 4.
- the other end of the first branch portion 5a and the other end of the second branch portion 5b are opposed to each other to form a split 6.
- the first branch portion 5a, the second branch portion 5b, the split 6, and a part of the first radiating element 3 and a part of the second radiating element 4 form a C-shaped split ring resonator 8.
- the antenna 10 includes a connection element 7 that is a linear conductor pattern.
- One end of the connection element 7 is connected to a part of the first radiating element 3.
- the other end of the connection element 7 is connected to a part of the second radiating element 4.
- the connection element 7 includes the first radiating element 3 and the second radiating element so that the split 6 is not included in the region surrounded by the connecting element 7, the first radiating element 3, and the second radiating element 4. 4 is electrically connected.
- the antenna 10 according to the present embodiment is composed of the above-described conductor pattern formed of a copper foil on the surface layer of the printed circuit board 1, it can be manufactured at low cost by using an inexpensive single-layer substrate as the printed circuit board 1. .
- the antenna 10 according to the present embodiment does not necessarily use a single-layer substrate, and it is naturally conceivable to configure it in an arbitrary layer of a multilayer substrate, for example.
- the conductor pattern may be formed of sheet metal or the like as long as it can be manufactured at a low cost.
- the conductor pattern may be formed of various materials other than copper foil as long as it has conductivity. Further, the materials used as the conductor pattern may be the same material or different materials.
- FIG. 3 is a diagram showing an equivalent circuit of the split ring resonator 8 according to the first embodiment.
- FIG. 3A shows the feed point and the split ring resonator 8 in the antenna 10 according to the present embodiment
- FIG. 3B shows an equivalent circuit corresponding to the part.
- the current fed from the antenna feeding point 2 flows in a ring shape through the split ring resonator 8 to generate an inductance. Further, a capacitance is generated between the conductor patterns facing each other at the split 6. Since these inductance and capacitance are connected in series, the split ring resonator 8 forms an LC series resonance circuit and operates as an antenna that radiates electromagnetic waves in the space near the resonance frequency.
- the whole antenna is responsible for resonance, and it has been difficult to make the length of the whole antenna smaller than about half of the wavelength of electromagnetic waves at the operating frequency.
- the operating frequency of the antenna 10 increases the inductance by increasing the ring length of the split ring resonator 8 or increasing the capacitance by decreasing the interval between the opposing conductor patterns of the split 6. It is possible to easily lower the resonance frequency.
- the method of increasing the capacitance of the split 6 increases the loss because the electric field concentrates on the split 6, while the operating frequency can be lowered without increasing the overall size. A small antenna can be realized.
- the antenna 10 according to the present embodiment greatly improves the radiation efficiency by inducing a part of the current flowing through the split ring resonator 8 to the first radiating element 3 and the second radiating element 4.
- the radiation efficiency of the antenna 10 according to the present embodiment can be improved by increasing the lengths of the first radiation element 3 and the second radiation element 4.
- the antenna 10 according to the present embodiment easily controls the impedance of the antenna viewed from the antenna feeding point 2 by changing the connection position of the connection element 7 with the first radiating element 3 and the second radiating element 4. be able to.
- the connection position between the connection element 7 and the first radiation element 3 is different from that in FIG. 1, and the open end of the first radiation element 3, the first branch portion 5 a, and the first radiation. It can also be between the connection position with the element 3.
- the connection position between the connection element 7 and the second radiating element 4 is different from that in FIG. 1, and the connection position between the open end of the second radiating element 4 and the second branch portion 5 b and the second radiating element 4. It can also be between.
- the antenna 10 according to the present embodiment can efficiently feed power to the antenna by matching the characteristic impedance of the transmission line and the impedance of the antenna without using an impedance matching circuit.
- FIG. 4 shows a Smith chart showing the impedance characteristics of the antenna 10 according to the first embodiment and FIG. 5 shows a return loss characteristic when a 2.4 GHz band wireless LAN is assumed.
- the length from the tip of the first radiating element 3 to the tip of the second radiating element 4 was 40 mm.
- the impedance curve passes through the vicinity of the center in the band from 2400 MHz to 2500 MHz used in the 2.4 GHz band wireless LAN, and the impedance is well matched.
- the return loss characteristics of FIG. 5 it can be seen that the reflection is small in the corresponding frequency band, and the impedance is well matched.
- FIG. 5 shows a conventional example.
- FIG. 6 shows a Smith chart of a dipole antenna having the same length of 40 mm
- FIG. 7 shows a return loss characteristic. 6 and 7, although having the same length, the resonance frequency is 3000 MHz or more, and only a return loss of about ⁇ 2 dB is obtained in the band from 2400 MHz to 2500 MHz used in the wireless LAN. This is because the length of the dipole antenna is shorter than 1 ⁇ 2 of the wavelength, and it can be seen that a longer element is required for use in the wireless LAN band.
- the antenna 10 according to the present embodiment can reduce the size of the antenna as compared with the conventional antenna. Further, the antenna 10 according to the present embodiment does not need to insert a predetermined impedance matching circuit, and can be manufactured by a general manufacturing process of a printed circuit board. Therefore, according to the present embodiment, it is possible to provide an antenna that is small in size and can be manufactured at low cost.
- At least one antenna 10 as described above can be provided in a wireless communication device having a communication function.
- a wireless communication apparatus can reduce the size of the antenna 10, so that the entire apparatus can be reduced in size.
- the case where the first radiating element 3 and the second radiating element 4 are linear is shown as an example.
- the shape of the first radiating element 3 and the second radiating element 4 is not necessarily linear.
- the shape of the 1st radiation element 3 and the 2nd radiation element 4 may be a polygonal line shape.
- the shape of the first radiating element 3 and the second radiating element 4 is such that the width is widened to the side where the first branching portion 5a and the second branching portion 5b are connected. May be. Further, for example, as shown in FIG.
- the shapes of the first radiating element 3 and the second radiating element 4 may be further widened on the side to which the connection element 7 is connected. 8, 9, and 10, similarly to FIG. 1, the first branch portion 5 a, the second branch portion 5 b, the split 6, a part of the first radiating element 3, and one part of the second radiating element 4 are used.
- the portion forms a split ring resonator 8 and operates as an antenna at the resonance frequency of the split ring resonator 8.
- the antenna feeding point 2 is provided in the center of the antenna 10, but the antenna feeding point 2 is not necessarily provided in the center of the antenna 10.
- the connection element 7 is connected to a position closer to the second branch portion 5b side than the center, corresponding to the position of the antenna feeding point 2.
- the antenna feeding point 2 may be arranged at a position closer to the first branching portion 5a than the center.
- the connection element 7 is connected to a position closer to the first branch portion 5a side than the center, corresponding to the position of the antenna feeding point 2.
- FIG. 1 shows an example in which the split 6 is configured such that the end portions of the first branch portion 5a and the second branch portion 5b are simply close to each other, but the split 6 has the first branch portion 5a and the first branch portion 5a.
- Any capacitance may be used as long as a capacitance is formed between the end portions of the two branch portions 5b.
- the split 6 has an interdigital shape in which the end portions of the first branch portions 5a and the end portions of the second branch portions 5b that are comb-shaped are arranged so as to mesh with each other. Also good. In this case, since the capacitance in the split 6 can be increased without increasing the size, the antenna 10 can be made smaller.
- the split 6 is provided at the center of the antenna 10, but the split 6 is not necessarily provided at the center of the antenna 10.
- the split 6 may be provided at a position closer to the first branch portion 5a than the center.
- connection element 7 may be configured to be formed on the back surface of the printed circuit board 1.
- the connection element 7 is connected to the first radiating element 3 and the second radiating element 4 by conductor vias formed in the printed circuit board 1.
- an antenna 20 according to a second embodiment of the present invention will be described with reference to the drawings.
- the second embodiment is the same as the antenna 10 according to the first embodiment except for the following points.
- symbol is attached
- connection element 7 is an elongated line
- one end of the connection element 7 is connected to a part of the first radiating element 3 and the other end is the first.
- the first radiating element 3 and the second radiating element 3 are connected to a part of the radiating element 4 and the split 6 is not included in the region surrounded by the connecting element 7, the first radiating element 3 and the second radiating element 4. Any shape may be used as long as the radiation element 4 is electrically connected.
- FIG. 14 is a top view showing the configuration of the antenna 20 according to the second embodiment.
- the antenna 20 shown in FIG. 14 includes a ground plane 21 instead of the connection element 7 based on the antenna of FIG. 8 of the first embodiment.
- the ground plane 21 is a plane-shaped conductor formed on the printed circuit board 1 and includes a notch 22 on at least one side.
- the rectangular cutout 22 is illustrated, but the shape of the cutout 22 is not limited to this.
- the shape of the notch 22 may be an arc shape or a polygon other than a rectangle.
- the first radiating element 3 is connected to a side of the ground plane 21 having the notch 22 and a position different from the notch 22.
- the second radiating element 4 is connected to a side of the ground plane 21 having the cutout portion 22, which is opposite to the position where the first radiating element 3 is connected to the cutout portion 22.
- the antenna feeding point 2 is disposed inside the notch 22, and the split 6 is disposed on the opposite side of the ground plane 21 with respect to the antenna feeding point 2.
- the first radiating element 3 is configured so that the ground plane 21 does not include the split 6 inside the region surrounded by the ground plane 21, the first radiating element 3, and the second radiating element 4. And the second radiating element 4 are electrically connected.
- the ground plane 21 in this embodiment operates in exactly the same manner as the connection element 7 in the first embodiment.
- the antenna 20 in the present embodiment easily controls the impedance of the antenna viewed from the antenna feeding point 2 by changing the connection position of the ground plane 21 and the first radiating element 3 and the second radiating element 4. be able to.
- the characteristic impedance of the transmission line and the impedance of the antenna can be matched without using an impedance matching circuit, and power can be efficiently supplied to the antenna.
- the ground plane 21 is connected to components such as LSI (Large Scale Integration) and IC (Integrated Circuit) (not shown), and can provide a ground potential or other power supply potential.
- FIG. 14 shows an example in which components and wirings are not arranged in the area of the ground plane 21, but components and wirings such as LSIs and ICs may be arranged in the area of the ground plane 21.
- a configuration in which an RF (Radio Frequency) circuit connected to the antenna feeding point 2 is provided on a partial region of the printed circuit board 1 can be employed.
- FIG. 15 shows a Smith chart representing the impedance characteristics of the antenna 20 according to the second embodiment and FIG. 16 shows the return loss characteristics assuming a 2.4 GHz band wireless LAN.
- the length from the tip of the first radiating element 3 to the tip of the second radiating element 4 was 40 mm.
- the impedance curve passes through the vicinity of the center in the band from 2400 MHz to 2500 MHz used in the 2.4 GHz band wireless LAN, and the impedance is well matched.
- the return loss characteristic of FIG. 16 it can be seen that the reflection is small in the corresponding frequency band, and the impedance is well matched.
- the antenna 20 according to the present embodiment can reduce the size of the antenna as compared with the conventional antenna, similarly to the antenna 10 according to the first embodiment. Further, it is not necessary to insert a predetermined impedance matching circuit, and the printed circuit board can be manufactured by a general manufacturing process. Therefore, according to this embodiment, it is possible to provide an antenna that can be manufactured at a low cost while being small.
- At least one antenna 20 as described above can be provided in a wireless communication device having a communication function.
- a wireless communication apparatus can reduce the size of the antenna 20, so that the entire apparatus can be reduced in size.
- the configuration shown in the second embodiment described above is merely an example, and for example, the following modes may be used.
- 17 to 19 used in the following description are top views showing other configurations of the antenna 20 according to the second embodiment.
- the antenna 20 shown in FIG. 17 is based on FIG. 14, and the ground plane 21 and the first radiating element 3 are connected not only on the side having the cutout portion of the ground plane 21 but also inside the cutout portion 22. ing. Further, the ground plane 21 and the second radiating element 4 are connected not only on the side having the cutout portion of the ground plane 21 but also inside the cutout portion 22.
- the first radiating element 3 and the second radiating element 4 can be formed as a conductor pattern substantially integral with the ground plane 21, and the first radiating element 3 and the second radiating element 4 can be formed. Parts and wiring can be arranged closer to each other.
- the antenna 20 shown in FIG. 18 is based on FIG. 11, and the other configuration is the same as that of FIG. Also in this case, similarly to the antenna 20 of FIG. 14, the impedance of the antenna viewed from the antenna feeding point 2 can be easily changed by changing the connection position between the ground plane 21 and the first radiating element 3 and the second radiating element 4. Can be controlled. As a result, the characteristic impedance of the transmission line and the impedance of the antenna can be matched without using an impedance matching circuit, and power can be efficiently supplied to the antenna.
- the antenna 20 shown in FIG. 19 is based on FIG. 18, and the ground plane 21 and the first radiating element 3 are not only on the side having the cutout portion of the ground plane 21 but also inside the cutout portion 22. It is connected.
- the first radiating element 3 can be formed as a conductor pattern substantially integrated with the ground plane 21, and components and wirings can be arranged closer to the first radiating element 3. It becomes.
- the ground plane 21 and the second radiating element 4 may be connected not only on the side having the cutout portion of the ground plane 21 but also inside the cutout portion 22.
- the second radiating element 4 can be formed as a conductor pattern substantially integrated with the ground plane 21, and components and wirings can be arranged closer to the second radiating element 4. It becomes.
- An antenna feed point comprising a first terminal and a second terminal; A conductive first radiating element connected to the first terminal; A conductive second radiating element connected to the second terminal; A conductive first branch portion having one end connected to a position other than the end of the first radiating element; A conductive second branch portion having one end connected to a position other than the end of the second radiating element; A conductive connecting element connecting a part of the first radiating element and a part of the second radiating element; The other end of the first branch portion and the other end of the second branch portion are opposed to each other to form a capacitor portion, The capacitor portion is located outside a region surrounded by the connection element, the first radiating element, and the second radiating element, A part of the first radiating element, a part of the second radiating element, the first branching part, the second branching part, and the capacitive part form a split ring resonator.
- the antenna 2.
- the capacitor is in an interdigital shape.
- the first and second radiating elements are linear; 1. Or 2. Antenna described in. 4).
- the connecting element is linear; 1. To 3.
- the connection element is a conductive plane having a side formed in a straight line at least at a part of the outer periphery thereof, the side is provided with a notch, and on both sides of the notch
- the first radiating element and the second radiating element are connected to each other, and the antenna feeding point is disposed inside the notch. 1. To 3.
- the shape of the notch is a rectangle, 5. Antenna described in. 7).
- An antenna feed point comprising a first terminal and a second terminal; A conductive first radiating element connected to the first terminal; A conductive second radiating element connected to the second terminal; A conductive first branch portion having one end connected to a position other than the end of the first radiating element; A conductive second branch portion having one end connected to a position other than the end of the second radiating element; A conductive connecting element connecting a part of the first radiating element and a part of the second radiating element; The other end of the first branch portion and the other end of the second branch portion are opposed to each other to form a capacitor portion, The capacitor portion is located outside a region surrounded by the connection element, the first radiating element, and the second radiating element, An antenna in which a part of the first radiating element, a part of the second radiating element, the first branch part, the second branch part, and the capacitor part form a split ring resonator.
- a printed circuit board comprising at least one of the above. 8).
- the capacitor is in an interdigital shape. 7).
- the first and second radiating elements are linear; 7). Or 8.
- the connecting element is linear; 7).
- the connection element is a conductive plane having a side formed in a straight line at least at a part of the outer periphery thereof, the side is provided with a notch, and on both sides of the notch
- the first radiating element and the second radiating element are connected to each other, and the antenna feeding point is disposed inside the notch. 7).
- To 10. The printed circuit board as described in any one of these.
- An antenna feed point comprising a first terminal and a second terminal; A conductive first radiating element connected to the first terminal; A conductive second radiating element connected to the second terminal; A conductive first branch portion having one end connected to a position other than the end of the first radiating element; A conductive second branch portion having one end connected to a position other than the end of the second radiating element; A conductive connecting element connecting a part of the first radiating element and a part of the second radiating element; The other end of the first branch portion and the other end of the second branch portion are opposed to each other to form a capacitor portion, The capacitor portion is located outside a region surrounded by the connection element, the first radiating element, and the second radiating element, An antenna in which a part of the first radiating element, a part of the second radiating element, the first branch part, the second branch part, and the capacitor part form a split ring resonator.
- a wireless communication device comprising at least one of the above. 14
- the capacitor is in an interdigital shape.
- the first and second radiating elements are linear; 13. Or 14.
- the connecting element is linear; 13. To 15. The wireless communication device according to any one of the above. 17.
- the connection element is a conductive plane having a side formed in a straight line at least at a part of the outer periphery thereof, the side is provided with a notch, and on both sides of the notch The first radiating element and the second radiating element are connected to each other, and the antenna feeding point is disposed inside the notch. 13. To 15. The wireless communication device according to any one of the above. 18.
- the shape of the notch is a rectangle, 17.
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Abstract
Description
第1の端子と第2の端子を備えたアンテナ給電点と、
前記第1の端子と接続された導電性の第1放射エレメントと、
前記第2の端子と接続された導電性の第2放射エレメントと、
前記第1放射エレメントの端部でない位置に一端が接続された導電性の第1分岐部と、
前記第2放射エレメントの端部でない位置に一端が接続された導電性の第2分岐部と、
前記第1放射エレメントの一部と、前記第2放射エレメントの一部と、を接続する導電性の接続エレメントとを備え、
前記第1分岐部の他端と前記第2分岐部の他端とが、互いに対向して容量部を形成しており、
前記容量部は、前記接続エレメントと、前記第1放射エレメントと、前記第2放射エレメントとで囲まれる領域の外側に位置しており、
前記第1放射エレメントの一部と、前記第2放射エレメントの一部と、前記第1分岐部と、前記第2分岐部と、前記容量部とが、スプリットリング共振器を形成している、
アンテナが提供される。
第1の端子と第2の端子を備えたアンテナ給電点と、
前記第1の端子と接続された導電性の第1放射エレメントと、
前記第2の端子と接続された導電性の第2放射エレメントと、
前記第1放射エレメントの端部でない位置に一端が接続された導電性の第1分岐部と、
前記第2放射エレメントの端部でない位置に一端が接続された導電性の第2分岐部と、
前記第1放射エレメントの一部と、前記第2放射エレメントの一部と、を接続する導電性の接続エレメントとを備え、
前記第1分岐部の他端と前記第2分岐部の他端とが、互いに対向して容量部を形成しており、
前記容量部は、前記接続エレメントと、前記第1放射エレメントと、前記第2放射エレメントとで囲まれる領域の外側に位置しており、
前記第1放射エレメントの一部と、前記第2放射エレメントの一部と、前記第1分岐部と、前記第2分岐部と、前記容量部とが、スプリットリング共振器を形成しているアンテナを、少なくとも一つ備えるプリント基板が提供される。
第1の端子と第2の端子を備えたアンテナ給電点と、
前記第1の端子と接続された導電性の第1放射エレメントと、
前記第2の端子と接続された導電性の第2放射エレメントと、
前記第1放射エレメントの端部でない位置に一端が接続された導電性の第1分岐部と、
前記第2放射エレメントの端部でない位置に一端が接続された導電性の第2分岐部と、
前記第1放射エレメントの一部と、前記第2放射エレメントの一部と、を接続する導電性の接続エレメントとを備え、
前記第1分岐部の他端と前記第2分岐部の他端とが、互いに対向して容量部を形成しており、
前記容量部は、前記接続エレメントと、前記第1放射エレメントと、前記第2放射エレメントとで囲まれる領域の外側に位置しており、
前記第1放射エレメントの一部と、前記第2放射エレメントの一部と、前記第1分岐部と、前記第2分岐部と、前記容量部とが、スプリットリング共振器を形成しているアンテナを、少なくとも一つ備える無線通信装置が提供される。
以下、本発明の第一の実施形態によるアンテナ10を、図面を参照して説明する。
以下、本発明の第二の実施形態によるアンテナ20を、図面を参照して説明する。第二の実施形態は以下の点を除いて第一の実施形態によるアンテナ10と同様である。なお、第一の実施形態によるアンテナ10と共通する構成要素については同一の符号を付し、説明を省略する。
1.
第1の端子と第2の端子を備えたアンテナ給電点と、
前記第1の端子と接続された導電性の第1放射エレメントと、
前記第2の端子と接続された導電性の第2放射エレメントと、
前記第1放射エレメントの端部でない位置に一端が接続された導電性の第1分岐部と、
前記第2放射エレメントの端部でない位置に一端が接続された導電性の第2分岐部と、
前記第1放射エレメントの一部と、前記第2放射エレメントの一部と、を接続する導電性の接続エレメントとを備え、
前記第1分岐部の他端と前記第2分岐部の他端とが、互いに対向して容量部を形成しており、
前記容量部は、前記接続エレメントと、前記第1放射エレメントと、前記第2放射エレメントとで囲まれる領域の外側に位置しており、
前記第1放射エレメントの一部と、前記第2放射エレメントの一部と、前記第1分岐部と、前記第2分岐部と、前記容量部とが、スプリットリング共振器を形成している、
アンテナ。
2.
前記容量部はインターデジタル形状である、
1.に記載のアンテナ。
3.
前記第1及び第2放射エレメントは線状である、
1.または2.に記載のアンテナ。
4.
前記接続エレメントは線状である、
1.から3.のいずれか一つに記載のアンテナ。
5.
前記接続エレメントは、直線状に形成された辺を、少なくともその外周の一部に有する導電性プレーンであり、前記辺には切り欠き部が備えられており、前記切り欠き部を挟んだ両側には、前記第1放射エレメントと前記第2放射エレメントがそれぞれ接続されており、前記アンテナ給電点が前記切り欠き部の内部に配置されている、
1.から3.のいずれか一つに記載のアンテナ。
6.
前記切り欠き部の形状は長方形である、
5.に記載のアンテナ。
7.
第1の端子と第2の端子を備えたアンテナ給電点と、
前記第1の端子と接続された導電性の第1放射エレメントと、
前記第2の端子と接続された導電性の第2放射エレメントと、
前記第1放射エレメントの端部でない位置に一端が接続された導電性の第1分岐部と、
前記第2放射エレメントの端部でない位置に一端が接続された導電性の第2分岐部と、
前記第1放射エレメントの一部と、前記第2放射エレメントの一部と、を接続する導電性の接続エレメントとを備え、
前記第1分岐部の他端と前記第2分岐部の他端とが、互いに対向して容量部を形成しており、
前記容量部は、前記接続エレメントと、前記第1放射エレメントと、前記第2放射エレメントとで囲まれる領域の外側に位置しており、
前記第1放射エレメントの一部と、前記第2放射エレメントの一部と、前記第1分岐部と、前記第2分岐部と、前記容量部とが、スプリットリング共振器を形成しているアンテナを、少なくとも一つ備えるプリント基板。
8.
前記容量部はインターデジタル形状である、
7.に記載のプリント基板。
9.
前記第1及び第2放射エレメントは線状である、
7.または8.に記載のプリント基板。
10.
前記接続エレメントは線状である、
7.から10.のいずれか一つに記載のプリント基板。
11.
前記接続エレメントは、直線状に形成された辺を、少なくともその外周の一部に有する導電性プレーンであり、前記辺には切り欠き部が備えられており、前記切り欠き部を挟んだ両側には、前記第1放射エレメントと前記第2放射エレメントがそれぞれ接続されており、前記アンテナ給電点が前記切り欠き部の内部に配置されている、
7.から10.のいずれか一つに記載のプリント基板。
12.
前記切り欠き部の形状は長方形である、
11.に記載のプリント基板。
13.
第1の端子と第2の端子を備えたアンテナ給電点と、
前記第1の端子と接続された導電性の第1放射エレメントと、
前記第2の端子と接続された導電性の第2放射エレメントと、
前記第1放射エレメントの端部でない位置に一端が接続された導電性の第1分岐部と、
前記第2放射エレメントの端部でない位置に一端が接続された導電性の第2分岐部と、
前記第1放射エレメントの一部と、前記第2放射エレメントの一部と、を接続する導電性の接続エレメントとを備え、
前記第1分岐部の他端と前記第2分岐部の他端とが、互いに対向して容量部を形成しており、
前記容量部は、前記接続エレメントと、前記第1放射エレメントと、前記第2放射エレメントとで囲まれる領域の外側に位置しており、
前記第1放射エレメントの一部と、前記第2放射エレメントの一部と、前記第1分岐部と、前記第2分岐部と、前記容量部とが、スプリットリング共振器を形成しているアンテナを、少なくとも一つ備える無線通信装置。
14.
前記容量部はインターデジタル形状である、
13.に記載の無線通信装置。
15.
前記第1及び第2放射エレメントは線状である、
13.または14.に記載の無線通信装置。
16.
前記接続エレメントは線状である、
13.から15.のいずれか一つに記載の無線通信装置。
17.
前記接続エレメントは、直線状に形成された辺を、少なくともその外周の一部に有する導電性プレーンであり、前記辺には切り欠き部が備えられており、前記切り欠き部を挟んだ両側には、前記第1放射エレメントと前記第2放射エレメントがそれぞれ接続されており、前記アンテナ給電点が前記切り欠き部の内部に配置されている、
13.から15.のいずれか一つに記載の無線通信装置。
18.
前記切り欠き部の形状は長方形である、
17.に記載の無線通信装置。
Claims (8)
- 第1の端子と第2の端子を備えたアンテナ給電点と、
前記第1の端子と接続された導電性の第1放射エレメントと、
前記第2の端子と接続された導電性の第2放射エレメントと、
前記第1放射エレメントの端部でない位置に一端が接続された導電性の第1分岐部と、
前記第2放射エレメントの端部でない位置に一端が接続された導電性の第2分岐部と、
前記第1放射エレメントの一部と、前記第2放射エレメントの一部と、を接続する導電性の接続エレメントとを備え、
前記第1分岐部の他端と前記第2分岐部の他端とが、互いに対向して容量部を形成しており、
前記容量部は、前記接続エレメントと、前記第1放射エレメントと、前記第2放射エレメントとで囲まれる領域の外側に位置しており、
前記第1放射エレメントの一部と、前記第2放射エレメントの一部と、前記第1分岐部と、前記第2分岐部と、前記容量部とが、スプリットリング共振器を形成している、
アンテナ。 - 前記容量部はインターデジタル形状である、
請求項1に記載のアンテナ。 - 前記第1及び第2放射エレメントは線状である、
請求項1または請求項2に記載のアンテナ。 - 前記接続エレメントは線状である、
請求項1から請求項3のいずれか一項に記載のアンテナ。 - 前記接続エレメントは、直線状に形成された辺を、少なくともその外周の一部に有する導電性プレーンであり、前記辺には切り欠き部が備えられており、前記切り欠き部を挟んだ両側には、前記第1放射エレメントと前記第2放射エレメントがそれぞれ接続されており、前記アンテナ給電点が前記切り欠き部の内部に配置されている、
請求項1から請求項3のいずれか一項に記載のアンテナ。 - 前記切り欠き部の形状は長方形である、
請求項5に記載のアンテナ。 - 第1の端子と第2の端子を備えたアンテナ給電点と、
前記第1の端子と接続された導電性の第1放射エレメントと、
前記第2の端子と接続された導電性の第2放射エレメントと、
前記第1放射エレメントの端部でない位置に一端が接続された導電性の第1分岐部と、
前記第2放射エレメントの端部でない位置に一端が接続された導電性の第2分岐部と、
前記第1放射エレメントの一部と、前記第2放射エレメントの一部と、を接続する導電性の接続エレメントとを備え、
前記第1分岐部の他端と前記第2分岐部の他端とが、互いに対向して容量部を形成しており、
前記容量部は、前記接続エレメントと、前記第1放射エレメントと、前記第2放射エレメントとで囲まれる領域の外側に位置しており、
前記第1放射エレメントの一部と、前記第2放射エレメントの一部と、前記第1分岐部と、前記第2分岐部と、前記容量部とが、スプリットリング共振器を形成しているアンテナを、少なくとも一つ備えるプリント基板。 - 第1の端子と第2の端子を備えたアンテナ給電点と、
前記第1の端子と接続された導電性の第1放射エレメントと、
前記第2の端子と接続された導電性の第2放射エレメントと、
前記第1放射エレメントの端部でない位置に一端が接続された導電性の第1分岐部と、
前記第2放射エレメントの端部でない位置に一端が接続された導電性の第2分岐部と、
前記第1放射エレメントの一部と、前記第2放射エレメントの一部と、を接続する導電性の接続エレメントとを備え、
前記第1分岐部の他端と前記第2分岐部の他端とが、互いに対向して容量部を形成しており、
前記容量部は、前記接続エレメントと、前記第1放射エレメントと、前記第2放射エレメントとで囲まれる領域の外側に位置しており、
前記第1放射エレメントの一部と、前記第2放射エレメントの一部と、前記第1分岐部と、前記第2分岐部と、前記容量部とが、スプリットリング共振器を形成しているアンテナを、少なくとも一つ備える無線通信装置。
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