RU2366045C1 - Antenna - Google Patents

Abstract

FIELD: radio engineering.

SUBSTANCE: invention relates to wideband small-sized surface-mounting antenna. Proposed antenna incorporates inductors (L1) and (L2) coupled magnetically, resonance LC-type circuit consisting of inductor (L1) and capacitors (C1a) and (C1b), as well as resonance LC-type circuit consisting of inductor (L2) and capacitors (C2a) and (C2b). To emit electromagnetic waves, multiple resonance LC-type circuits are used to make matching circuit to match impedance (50Ω) of the device to be coupled with supply terminals (5) and (6) and with impedance of free space irradiation (377Ω).

EFFECT: wider frequency range.

11 cl, 32 dwg

Description

FIELD OF THE INVENTION

The present invention relates to antennas, and more particularly to a broadband small surface mount antenna.

BACKGROUND

Patent Document 1 discloses a helical antenna as a compact antenna used in mobile communications, such as mobile phones. In the spiral antenna disclosed in Patent Document 1, the drive coil is wound in a spiral around a long and narrow dielectric main body, and the first and second non-power coils are wound in a spiral around the main body so that they are adjacent to the drive coil. Thus, the spiral antenna is configured to operate in two frequency ranges.

However, these two frequency ranges within which the spiral antenna can operate are located relative to each other with an interval of at least several hundred megahertz, and between these two frequency ranges it is impossible to establish an interval of 100 MHz or less. In addition, a sufficiently wide frequency band cannot be achieved, although the width of each frequency band is greater than the bandwidth of a single coil helical antenna.

Patent Document 1: Publication of Japanese Unexamined Patent Application No. 2003-37426.

SUMMARY OF THE INVENTION

Tasks to be Solved Using the Present Invention.

An object of the present invention is to provide a small antenna in which a wide frequency range is achievable.

Means for solving these problems

To solve the aforementioned problem, the first invention provides an antenna including a power terminal and at least two inductance elements having different inductance values. Inductors are used to emit electromagnetic waves. Inductors are used as inductances of the matching circuit to match the impedance of a device designed to connect to the supply terminal and the free-space radiation impedance.

In the antenna according to the first invention, the use of at least two inductance elements having different inductances in the form of inductances of the matching circuit allows the impedance of the device connected to the supply terminal to be matched with the impedance of the 377Ω space in a substantially wide frequency band. Accordingly, a small antenna having a wide frequency band can be realized, and the antenna can be a surface mount antenna.

The second invention provides an antenna including a power terminal and a plurality of resonant circuits. Many resonant circuits are used to emit electromagnetic waves. A plurality of resonant circuits is used as a matching circuit to match the impedance of a device designed to be connected to the supply terminal and the free-space radiation impedance.

In the antenna according to the second invention, when using the inductance components of a plurality of resonant circuits for emitting electromagnetic waves as the inductance of the matching circuit, the impedance of the device connected to the supply terminal can be matched to the impedance of the space 377Ω in a substantially wide frequency band. Therefore, it is possible to realize a small antenna having a wide frequency band, and the antenna may be a surface mount antenna.

According to a second invention, each of the plurality of resonant circuits may include a capacitance element and an inductance element. In this case, it is preferable that the plurality of resonant circuits are electrically connected to the supply terminal directly or through a concentrated constant capacitance or inductance. The coupling coefficient between adjacent resonant circuits among the plurality of resonant circuits preferably has a value of at least 0.1.

The inductance element in each resonant circuit can be composed of linear electrode patterns located in the direction of one axis. Preferably, the capacitance element is electrically connected to the supply terminal to prevent voltage surges. When forming a capacitance element on a multilayer substrate, the capacitance element does not interfere with a reduction in antenna size. By forming a plurality of resonant circuits on a multilayer substrate, a small-sized antenna can be obtained, and a multi-layer process facilitates the production of small-sized antennas.

A third invention provides an antenna including first and second supply terminals and a plurality of resonant circuits. The antenna includes a first LC type resonant circuit comprising a first inductance element and first and second capacitance elements, the first capacitance element being electrically connected to one end of the first inductance element and the second capacitance element electrically connected to the other end of the first inductance element, and the second LC type resonant circuit comprising a second inductance element and a third and fourth capacitance element, the third capacitance element being electrically connected to one end of the second inductance element and the fourth capacitance element is electrically connected to the other end of the second inductance element. The first inductance element is magnetically coupled to the second inductance element. One of the ends of the first inductance element is electrically connected to the first supply terminal through the first capacitance element, and its other end is electrically connected to the second supply terminal through the second capacitance element. One of the ends of the second inductance element is electrically connected to the first supply terminal through the third and first capacitance elements, and the other end is electrically connected to the second supply terminal through the fourth and second capacitance elements.

In the antenna according to the third invention, the first and second LC resonant circuits are used to emit electromagnetic waves, the first and second inductance elements act as inductors of the matching circuit, and the impedance of the device connected to the first and second supply terminals can be matched to the impedance of the space 377Ω in substantially wider frequency band. In addition, the elements can be easily layered to implement a small surface mount antenna having a wide frequency band.

Benefits

According to the present invention, the impedance of a device connected to a supply terminal can be matched to an impedance of a space of 377Ω in a substantially wide frequency band in a plurality of inductance elements or a plurality of resonant circuits used to emit electromagnetic waves. Therefore, there is no need to provide a separate matching circuit, thus realizing a small antenna having a wide frequency band.

BRIEF DESCRIPTION OF THE DRAWINGS

1 is an equivalent circuit diagram of an antenna according to a first embodiment of the present invention.

Figure 2 shows a top view of the layered structure of the antenna according to the first embodiment of the present invention.

Figure 3 is a graph showing the reflection characteristics of an antenna according to a first embodiment of the present invention.

4 is an illustration showing the directivity of an antenna according to a first embodiment of the present invention.

5 is an X-Y diagram indicating the directivity of an antenna according to a first embodiment of the present invention.

6 is a Smith chart indicating the impedance of an antenna according to a first embodiment of the present invention.

7 is a block diagram of an equivalent antenna circuit according to a second embodiment of the present invention.

On Fig shows a top view of the layered structure of the antenna according to the second variant implementation of the present invention.

9 is a graph showing reflection characteristics of an antenna according to a second embodiment of the present invention.

10 is a block diagram of equivalent circuits obtained from transforming an antenna loop according to a second embodiment of the present invention.

11 is a block diagram of an equivalent antenna circuit according to a third embodiment of the present invention.

12 is a perspective view showing a view of an antenna according to a third embodiment of the present invention.

13 is a graph showing reflection characteristics of an antenna according to a third embodiment of the present invention.

FIG. 14 is a block diagram of an equivalent antenna circuit according to a fourth embodiment of the present invention.

15 is a plan view of a layered structure of an antenna according to a fourth embodiment of the present invention.

FIG. 16 is a graph showing reflection characteristics of an antenna according to a fourth embodiment of the present invention.

17 is an equivalent circuit diagram of an antenna according to a fifth embodiment of the present invention.

On Fig shows a top view of the layered structure of the antenna according to the fifth embodiment of the present invention.

FIG. 19 is a block diagram of an equivalent antenna circuit according to a sixth embodiment of the present invention.

20 is a plan view of a layered structure of an antenna according to a sixth embodiment of the present invention.

21 is a block diagram of equivalent antenna circuits according to other embodiments of the present invention.

FIG. 22 is a block diagram of an equivalent antenna circuit according to a seventh embodiment of the present invention.

23 is a graph showing reflection characteristics of an antenna according to a seventh embodiment of the present invention.

24 is an equivalent circuit diagram of an antenna according to an eighth embodiment of the present invention.

25 is a graph showing reflection characteristics of an antenna according to an eighth embodiment of the present invention.

FIG. 26 is a block diagram of an equivalent antenna circuit according to a ninth embodiment of the present invention.

27 is a graph showing reflection characteristics of an antenna according to a ninth embodiment of the present invention.

28 is an equivalent circuit diagram of an antenna according to a tenth embodiment of the present invention.

On Fig shows a top view of the layered structure of the antenna according to the tenth embodiment of the present invention.

30 is a graph showing reflection characteristics of an antenna according to a tenth embodiment of the present invention.

FIG. 31 is a block diagram of an equivalent antenna circuit according to an eleventh embodiment of the present invention.

32 is a graph showing reflection characteristics of an antenna according to an eleventh embodiment of the present invention.

DETAILED DESCRIPTION OF THE INVENTION

In the present description, embodiments of the antenna according to the present invention are described with reference to the accompanying drawings.

(First Embodiment, FIGS. 1-6)

Antenna 1A according to the first embodiment of the present invention includes inductance elements L1 and L2 having different inductance values and in-phase magnetically coupled to each other (denoted by mutual inductance M), as shown in equivalent circuit diagram in FIG. 1. The inductance element L1 is connected to the supply terminals 5 and 6 through the capacitance elements C1a and C1b, respectively, and connected in parallel with the inductance element L2 through the capacitance elements C2a and C2b. In other words, this resonant circuit includes an LC type resonant circuit composed of inductance element L1 and capacitance elements C1a and C1b, and an LC type resonant circuit composed of inductance element L2 and capacitance elements C2a and C2b.

An antenna 1A having the aforementioned loop configuration has, for example, the layered structure shown in FIG. 2. Ceramic sheets 11a-11i made of dielectric material are laminated, pressed and fired to form an antenna 1A. In particular, the sheet 11a has supply terminals 5 and 6 formed thereon and through-through interconnects 19a and 19b. The sheet 11b has capacitor electrodes 12a and 12b formed thereon. The sheet 11c has capacitor electrodes 13a and 13b formed thereon and through-wirings 19c and 19d. The sheet 11d has capacitor electrodes 14a and 14b formed thereon, through-through interconnects 19c and 19d and through-through interconnects 19e and 19f.

In addition, the sheet 11e has patterns of connecting wires 15a, 15b and 15c formed thereon, an end-to-end interconnect 19d and an end-to-end interconnects 19g, 19h and 19i. The sheet 11f has wire patterns 16a and 17a formed thereon, through-through interconnects 19g and 19i, and through-through interconnects 19j and 19k. The sheet 11g has wire patterns 16b and 17b formed thereon and end-to-end interconnects 19g, 19i, 19j and 19k. The sheet 11h has wire patterns 16c and 17c formed thereon and end-to-end interconnects 19g, 19i, 19j and 19k. The sheet 11i has wire patterns 16d and 17d formed thereon.

When the sheets 11a-11i are layered on top of each other, the patterns of wires 16a-16d are connected to each other via an end-to-end interconnect 19j, forming an inductance element L1, and the patterns of wires 17a-17d are connected to each other via an end-to-end interconnect 19k, forming an inductance element L2. The capacitance element C1a is composed of electrodes 12a and 13a, and the capacitance element C1b is composed of electrodes 12b and 13b. The capacitance element C2a is composed of electrodes 13a and 14a, and the capacitance element C2b is composed of electrodes 13b and 14b.

One end of the inductance element L1 is connected to the capacitor electrode 13a through the through-wire interconnect 19g, the pattern of the connecting wire 15c and the through-wire interconnect 19c. The other end of the inductance element L1 is connected to the capacitor electrode 13b through the through-wiring 19d. One end of the inductance element L2 is connected to the capacitor electrode 14a via the through-wire interconnect 19i, the pattern of the connecting wire 15a, and the through-wire interconnect 19e. The other end of the inductance element L2 is connected to the capacitor electrode 14b through the through-wire interconnect 19h, the pattern of the connecting wire 15b and the through-wire interconnect 19f.

The supply terminal 5 is connected to the capacitor electrode 12a through the through-wiring 19a, and the supply terminal 6 is connected to the capacitor electrode 12b through the through-wiring 19b.

In the antenna 1A having the above configuration, LC type resonant circuits, which include inductance elements L1 and L2 magnetically coupled to each other, resonate, causing the inductance elements L1 and L2 to function as a radiating element. In addition, the connection between the inductance elements L1 and L2 through the capacitance elements C2a and C2b forms a matching circuit for matching the impedance (usually 50Ω) of the device connected to the supply terminals 5 and 6 with the free space impedance (377Ω).

The coupling coefficient k between adjacent inductance elements L1 and L2 is represented as k ² = M ² / (L1 × L2). The coupling coefficient k is preferably equal to or greater than 0.1, and in the first embodiment, the coupling coefficient k is approximately 0.8975. The values of the inductance elements L1 and L2 and the degree of magnetic coupling (mutual inductance M) between the inductance elements L1 and L2 are set so that the desired passband can be obtained. In addition, since the LC resonant circuits composed of the capacitance elements C1a, C1b, C2a and C2b and the inductance elements L1 and L2 are constructed as resonant circuits with constant lumped parameters, the circuits can be constructed as layered circuits having small dimensions, and these contours will be less affected by other elements. In addition, since the connection to the supply terminals 5 and 6 is made through the capacitance elements C1a and C1b, voltage surges at lower frequencies are prevented and the device is protected against overvoltage.

Since many LC type resonant circuits are formed on the multilayer substrate, the LC type resonant circuits can be designed as a small antenna that can be mounted on the substrate on the surface of, for example, a mobile phone. Antenna 1A can also be used as an antenna for a wireless device in the form of an integrated circuit used in a radio frequency identification (RFID) system.

As a result of the simulation performed by the inventor, based on the equivalent circuit shown in FIG. 1, the antenna 1A shows the reflection characteristics shown in FIG. 3. As can be seen in FIG. 3, the center frequency is 760 MHz and the antenna 1A exhibits reflection characteristics of −10 dB or lower in a wide frequency band from 700 MHz to 800 MHz. The reason why the reflection characteristics in the wide frequency band were obtained is described in more detail below in the second embodiment of the present invention.

Figure 4 shows the directivity of the antenna 1A. Figure 5 shows the directivity on the X-Y plane. The X, Y, and Z axes in FIG. 5 correspond to the arrows X, Y, and Z in FIGS. 2 and 4. FIG. 6 is a Smith chart illustrating the impedance of antenna 1A.

(Second Embodiment, Figs. 7-10)

Antenna 1B according to the second embodiment of the present invention includes inductance elements L1 and L2 having different inductance values and in-phase magnetically coupled to each other (denoted by mutual inductance M), as shown in equivalent circuit in FIG. 7. One of the ends of the inductance element L1 is connected to the supply terminal 5 via the capacitance element C1 and connected to the inductance element L2 through the capacitance element C2. The other ends of the inductance elements L1 and L2 are connected directly to the supply terminal 6. In other words, this resonance circuit includes an LC type resonant circuit composed of an inductance element L1 and a capacitance element C1, and an LC type resonant circuit composed of an inductance element L2 and cell element C2. The capacitance elements C1b and C2b in the antenna 1A according to the first embodiment of the present invention are not provided in the antenna 1B. The inductance of the inductance elements L1 and L2 and the magnetic coupling level (mutual inductance M) between the inductance elements L1 and L2 are set in such a way as to provide the desired passband.

An antenna 1B having the aforementioned loop configuration has, for example, a layered structure shown in FIG. Ceramic sheets 11a-11i made of dielectric material are laminated, pressed and fired to form an antenna 1B. As such, sheet 11a has supply terminals 5 and 6 formed thereon and through-through interconnects 19a and 19b. The sheet 11b has a capacitor electrode 12a formed thereon and a through wiring 19m. The sheet 11c has a capacitor electrode 13a formed thereon, a through wiring 19c and a through wiring 19m. The sheet 11d has a capacitor electrode 14a formed thereon, through-through interconnects 19c and 19m and a through-through interconnect 19e.

In addition, the sheet 11e has patterns of connecting wires 15a, 15b and 15c formed thereon and through-through interconnects 19d, 19g, 19h and 19i. The sheet 11f has wire patterns 16a and 17a formed thereon, through-through interconnects 19g and 19i, and through-through interconnects 19j and 19k. The sheet 11g has wire patterns 16b and 17b formed thereon and end-to-end interconnects 19g, 19i, 19j and 19k. The sheet 11h has wire patterns 16c and 17c formed thereon and end-to-end interconnects 19g, 19i, 19j and 19k. The sheet 11i has wire patterns 16d and 17d formed thereon.

When the sheets 11a-11i are stacked on top of each other, the wire patterns 16a-16d are connected to each other through the through-wire interconnect 19j, forming the inductance element L1, and the wire patterns 17a-17d are connected to each other through the through-wire interconnect 19k, forming the inductance element L2. The capacitance element C1 is composed of electrodes 12a and 13a. The cell element C2 is composed of electrodes 13a and 14a.

One end of the inductance element L1 is connected to the capacitor electrode 13a through the through-wire interconnect 19g, the pattern of the connecting wire 15c and the through-wire interconnect 19c. The other end of the inductance element L1 is connected to the supply terminal 6 via the through-wiring 19d, the pattern of the connecting wire 15b and the through-wiring 19m and 19b. The capacitor electrode 12a is connected to the supply terminal 5 via an end-to-end interconnect 19a.

One end of the inductance element L2 is connected to the capacitor electrode 14a via the through-wire interconnect 19i, the pattern of the connecting wire 15a, and the through-wire interconnect 19e. The other end of the inductance element L2 is connected to the supply terminal 6 through the through-wiring 19h, the pattern of the connecting wire 15b and the through-wiring 19m and 19b. The other end of the inductance element L1 is connected to the other end of the inductance element L2 by a pattern of the connecting wire 15b.

In the antenna 1B having the aforementioned configuration of LC type resonant circuits, which include inductance elements L1 and L2 magnetically coupled to each other, resonate, causing the inductance elements L1 and L2 to function as a radiating element. In addition, the connection between the inductance elements L1 and L2 through the capacitance element C2 forms a matching circuit for matching the impedance (usually 50Ω) of the device connected to the supply terminals 5 and 6 with the free space impedance (377Ω).

As a result of the simulation performed by the inventor, based on the equivalent circuit shown in FIG. 7, antenna 1B shows the reflection characteristics shown in FIG. 9.

The reason why the antenna 1B according to the second embodiment of the present invention has reflection characteristics in a wide frequency band is described in detail below. In FIG. 10 (A) shows the configuration of the antenna circuit 1B. Figure 10 (B) shows a circuit configuration in which part of the contour π, including the inductance element L1, capacitance element C2 and the inductance element L2 in Figure 10 (A), transformed into T. Addressing circuit 10 ( B), if L1 <L2, then L1-M≤0 due to the mutual inductance M. If L1-M = 0, the circuit shown in FIG. 10 (B) can be converted to the circuit shown in FIG. 10 (C). If L1-M <0, then the capacitance C2 in the circuit shown in FIG. 10 (C) is replaced by the capacitance C2 ′. The circuit in FIG. 10 (C), which is obtained by converting said circuit, includes a resonant circuit consisting of a capacitance C1 and a mutual inductance M, and a parallel resonant circuit consisting of a capacitor C2 and an inductance L2-M. Increasing the distance between the resonant frequencies of the resonant circuits expands the passband and allows you to achieve a wide frequency band. The passband is respectively set by setting the resonant frequencies, i.e. quantities L1, L2 and M.

(Third Embodiment, FIGS. 11-13)

The antenna 1C according to the third embodiment of the present invention includes blocks A, B and C, each of which includes two rows of LC resonant circuits, as shown in the equivalent circuit in FIG. 11. Since the LC type resonant circuit included in each of the blocks A, B and C has the same circuit configuration as the antenna 1A according to the first embodiment of the present invention, a detailed description of the LC type resonant circuits is omitted in this case.

In the antenna 1C, blocks A, B, and C, each of which has a layered structure shown in FIG. 2, are arranged in the manner illustrated in FIG. 12. The resonant-type circuits in blocks A, B, and C are connected to common supply terminals 5 and 6.

In the antenna 1C having the aforementioned configuration, LC type resonant circuits, which include magnetically coupled inductance elements L1 and L2, LC type resonant circuits, which include magnetically coupled inductance elements L3 and L4, and LC type resonant circuits, which include magnetically coupled inductance elements L5 and L6, resonate while functioning as a radiating element. In addition, the connection between the inductance elements through the capacitance elements forms a matching circuit for matching the impedance (usually 50Ω) of the device connected to the supply terminals 5 and 6 with the free space impedance (377Ω).

In other words, the antenna 1C according to the third embodiment of the present invention is obtained by parallel connection of the three antennas 1A according to the first embodiment of the present invention. As a result of the simulation performed by the inventor, based on the equivalent circuit shown in FIG. 11, the antenna 1C exhibits reflection characteristics of -10 dB or less in the three frequency bands T1, T2 and T3, as shown in FIG. 13. The T1 band corresponds to ultra-high frequency (UHF) television, the T2 band corresponds to the Global System for Mobile Communications (GSM), and the T3 band corresponds to a wireless local area network (LAN). Other operations and advantages according to the third embodiment of the present invention are similar to the operations and advantages according to the first embodiment of the present invention.

(Fourth Embodiment, Figs. 14-16)

Antenna 1D according to the fourth embodiment of the present invention includes inductance elements L1, L2, L3 and L4 having different inductance values and in-phase magnetically coupled to each other (indicated by mutual inductance M), as shown in equivalent circuit in FIG. 14 . The inductance element L1 is connected to the supply terminals 5 and 6 via capacitance elements C1a and C1b, respectively. An inductance element L2 is connected in parallel with an inductance element L1 through capacitance elements C2a and C2b. The inductance element L3 is connected in parallel with the inductance element L2 through the capacitance elements C3a and C3b. The inductance element L4 is connected in parallel with the inductance element L3 through capacitance elements C4a and C4b. In other words, said resonant circuit includes an LC type resonant circuit consisting of an inductance element L1 and capacitance elements C1a and C1b, an LC type resonant circuit consisting of an inductance element L2 and capacitance elements C2a and C2b, an LC type resonant circuit consisting of an inductance element L3 and capacitance elements C3a and C3b, and an LC type resonant circuit consisting of an inductance element L4 and capacitance elements C4a and C4b.

An antenna 1D having the aforementioned contour configuration has, for example, the layered structure shown in FIG. Ceramic sheets 21a-21j made of dielectric material are layered, pressed and fired to form an antenna 1D. In particular, the sheet 21a has capacitor electrodes 22a and 22b formed thereon, and the capacitor electrodes 22a and 22b also function as supply terminals 5 and 6. The sheet 21b has capacitor electrodes 23a and 23b formed on it and the through wiring 29a and 29b. The sheet 21c has capacitor electrodes 24a and 24b formed thereon, through wiring 29a and 29b, and through wiring 29c and 29d. The sheet 21d has capacitor electrodes 25a and 25b formed thereon, through wiring 29a to 29d and through wiring 29e and 29f. The sheet 21e has capacitor electrodes formed thereon 26a and 26b, through wiring 29a-29f and through wiring 29g and 29h.

Moreover, the sheet 21f has formed on it patterns of connecting wires 30a-30d and through the interconnects 28a-28h. The sheet 21g has wire patterns 31a-31d formed thereon and through wiring 27a-27h. The sheet 21h has wire patterns 31a-31d formed thereon and through wiring 27a-27h. The sheet 21i has wire patterns 31a-31d formed thereon and through wiring 27a-27h. The sheet 21j has patterns of connecting wires 32a-32d formed thereon.

When the sheets 21a-21j are stacked on top of each other, the wire patterns 31a-31d are connected to each other through the through-wire connections 27e-27h, forming inductance elements L1, L2, L3 and L4. One end of the inductance element L1 is connected to the electrode of the capacitance 23a through the through-wire connection 27e, the pattern of the connecting wire 32a, the through-wire connections 27a and 28a, the pattern of the connecting wire 30a and the through-wire 29a. The other end of the inductance element L1 is connected to the capacitor electrode 23b through the through connections 28e and 29b. One end of the inductance element L2 is connected to the capacitor electrode 24a through the through-wire connection 27f, the pattern of the connecting wire 32b, the through-wire connections 27b and 28b, the pattern of the connecting wire 30b and the through-wire 29c. The other end of the inductance element L2 is connected to the capacitor electrode 24b by means of through wiring 28f and 29d.

One end of the inductance element L3 is connected to the capacitor electrode 25a through the through-wire connection 27g, the pattern of the connecting wire 32c, the through-wire connections 27c and 28c, the pattern of the connecting wire 30c and the through-wire 29e. The other end of the inductance element L3 is connected to the capacitor electrode 25b through the through wiring 28g and 29f. One end of the inductance element L4 is connected to the capacitor electrode 26a via an end-to-end interconnect 27h, a pattern of the connecting wire 32d, the end-to-end interconnects 27d and 28d, the pattern of the connecting wire 30d and the end-to-end interconnect 29g. The other end of the inductance element L4 is connected to the capacitor electrode 26b through the through wiring 28h and 29h.

The capacitance element C1a consists of electrodes 22a and 23a, and the capacitance element C1b consists of electrodes 22b and 23b. The cell element C2a consists of electrodes 23a and 24a, and the cell element C2b consists of electrodes 23b and 24b. The cell element C3a consists of electrodes 24a and 25a, and the cell element C3b consists of electrodes 24b and 25b. The cell element C4a consists of electrodes 25a and 26a, and the cell element C4b consists of electrodes 25b and 26b.

In the antenna 1D having the aforementioned configuration, LC type resonant circuits including inductance elements L1-L4 magnetically coupled to each other resonate, causing the inductance elements L1-L4 to function as a radiating element. Moreover, the inductance element L2 is connected to the inductance element L1 through the capacitance elements C2a and C2b, the inductance element L3 is connected to the inductance element L2 through the capacitance elements C3a and C3b, and the inductance element L4 is connected to the inductance element L3 through the capacitance elements C4a and C4b. The connection between the inductance elements through the capacitance elements forms a matching circuit for matching the impedance (usually 50Ω) of the device connected to the supply terminals 5 and 6 with the free space impedance (377Ω).

The coupling coefficient k1 between adjacent inductance elements L1 and L2 is expressed as: k1 ² = M ² / (L1xL2), the coupling coefficient k2 between the inductance elements L2 and L3 is expressed as: k2 ² = M ² / (L2 × L3), and the coupling coefficient k3 between the inductance elements L3 and L4 is expressed as: k3 ² = M ² / (L3 × L4). The coupling coefficients k1, k2 and k3 are preferably equal to or greater than 0.1. The coupling coefficient k1 is approximately 0.7624, the coupling coefficient k2 is approximately 0.5750, and the coupling coefficient k3 is approximately 0.6627 according to a fourth embodiment of the present invention. The inductance values of the inductance elements L1-L4 and the coupling coefficients k1, k2 and k3 are set so as to obtain the desired bandwidth.

As a result of the simulation performed by the inventor based on the equivalent circuit shown in FIG. 14, the antenna 1D exhibits reflection characteristics of -6 dB or less within a very wide frequency band T4, as shown in FIG. 16. Other operations and advantages according to the fourth embodiment of the present invention are similar to the operations and advantages according to the first embodiment of the present invention.

(Fifth Embodiment, FIGS. 17 and 18)

Antenna 1E according to the fifth embodiment of the present invention includes inductance elements L1 and L2 having different inductance values and in-phase magnetically coupled to each other (denoted by mutual inductance M), as shown in the equivalent circuit in FIG. 17. An inductance element L1 is connected to the supply terminals 5 and 6 through capacitance elements C1a and C1b, respectively. The inductance element L1 and the capacitance elements C1a and C1b form an LC type resonant circuit. The inductance element L2 is connected in series with the capacitance element C2, forming an LC type resonant circuit.

An antenna 1E having the aforementioned loop configuration has, for example, a layered structure shown in FIG. Ceramic sheets 41a-41f made of dielectric material are layered, pressed and fired to form an antenna 1E. In particular, the sheet 41a has capacitor electrodes 42a and 42b formed thereon, and the capacitor electrodes 42a and 42b also function as supply terminals 5 and 6. The sheet 41b has capacitor electrodes 43a and 43b formed on it and the through connections 49a and 49b formed on it.

Moreover, the sheet 41c has formed on it patterns of connecting wires 44a and 45a and through the interconnects 49C, 49d, 49e and 49f. The sheet 41d has wire patterns 44b and 45b formed thereon and end-to-end interconnects 49g and 49h. The sheet 41e has a capacitor electrode 46 formed thereon and a through wiring 49i. The sheet 41f has a capacitor electrode 47 formed thereon.

When the sheets 41a-41f are stacked on top of each other, the patterns of wires 44a-44b are connected to each other via an end-to-end interconnect 49d, forming an inductance element L1, and the patterns of wires 45a and 45b are connected to each other through an end-to-end interconnect 49e, forming an inductance element L2. The capacitance element C1a consists of electrodes 42a and 43a, and the capacitance element C1b consists of electrodes 42b and 43b. The capacitance element C2 consists of electrodes 46 and 47.

One of the ends of the inductance element L1 is connected to the capacitor electrode 43a through the through wiring 49c and 49a. The other end of the inductance element L1 is connected to the capacitor electrode 43b through the through-wiring 49b. One end of the inductance element L2 is connected to the capacitor electrode 46 through the through-wiring connections 49f and 49h. The other end of the inductance element L2 is connected to the capacitor electrode 47 by means of through wiring 49g and 49i.

In the antenna 1E having the aforementioned configuration, LC type resonant circuits including inductance elements L1 and L2 magnetically coupled to each other resonate, causing the inductance elements L1 and L2 to function as a radiating element. Moreover, the magnetic coupling between the inductance elements L1 and L2 forms a matching circuit for matching the impedance (usually 50Ω) of the device connected to the supply terminals 5 and 6 with the free space impedance (377Ω).

The operation and advantages of the antenna 1E according to the fifth embodiment of the present invention are basically similar to the operations and advantages of the antenna 1A according to the first embodiment of the present invention.

(Sixth embodiment, Figs. 19 and 20)

Antenna 1F according to a sixth embodiment of the present invention includes inductance elements L1 and L2 having different inductance values and in-phase magnetically coupled to each other (denoted by mutual inductance M), as shown in an equivalent circuit in FIG. 19. An inductance element L1 is connected to the supply terminal 5 via a capacitance element 1C to form a resonance circuit LC type consisting of an inductance element L1 and a capacitance element C1. The inductance element L2 is connected in series with the capacitance element C2 to form an LC type resonant circuit. One of the ends of the inductance element L3 is connected to the supply terminal 6, and the other end thereof is connected to the inductance elements L1 and L2. The inductance of the inductance elements L1, L2 and L3 and the magnetic coupling level (mutual inductance M) between the inductance elements L1 and L2 are set so that the desired passband is obtained.

An antenna 1F having the aforementioned loop configuration has, for example, the layered structure shown in FIG. Ceramic sheets 51a-51h made of dielectric material are layered, pressed and fired to form an antenna 1F. In particular, the sheet 51a has supply terminals 5 and 6 formed thereon and through-through interconnects 59a and 59b. The sheet 51b has a capacitor electrode 52a formed thereon, a wire pattern 56a and an end-to-end interconnect 59c. The sheet 51c has a capacitor electrode 52b formed thereon, a wire pattern 56b, and end-to-end interconnects 59c and 59d.

In addition, the sheet 51d has wire patterns 53 and 56c formed thereon, an end-to-end interconnect 59c, and an end-to-end interconnect 59e. The sheet 51e has a wire pattern 56d, an end-to-end interconnect 59c, and an end-to-end interconnect 59f and 59g. The sheet 51f has a capacitor electrode 54a formed thereon, a wire pattern 56e, and end-to-end interconnects 59c and 59g. The sheet 51g has a capacitor electrode 54b formed thereon, a wire pattern 56f, end-to-end interconnects 59c and 59g, and an end-to-end interconnect 59h. The sheet 51h has a wire pattern 55 formed thereon. One of the ends of the wire pattern 55 serves as a wire pattern 56g.

Layering sheets 51a-51h on each other leads to the fact that the wire pattern 53 is formed as an inductance element L1, and the wire pattern 55 is formed as an inductance element L2. The wire patterns 56a-56g are connected through an end-to-end interconnect 59c, forming an inductance element L3. The capacitance element C1 consists of electrodes 52a and 52b, and the capacitance element C2 consists of electrodes 54a and 54b.

One end of the inductance element L1 is connected to the capacitor electrode 52b through the through-wiring 59d, and the other end is connected to the other end of the inductance element L2 through the through-wiring 59e and 59g. One end of the inductance element L2 is connected to the capacitor electrode 54b via the through-wire connection 59h. As described above, the other end of the inductance element L2 is connected to the other end of the inductance element L1 through end-to-end interconnects 59g and 59e and connected to one of the ends (wire pattern 56g) of the inductance element L3. The other end of the inductance element L3 is connected to the supply terminal 6 through the through-wiring 59b. The capacitor electrode 52a is connected to the supply terminal 5 via an end-to-end interconnect 59a.

In the antenna 1F having the aforementioned configuration, LC type resonant circuits including magnetically coupled inductance elements L1 and L2 resonate, causing the inductance elements L1 and L2 to function as a radiating element. Moreover, the magnetic coupling between the inductance elements L1 and L2 forms a matching circuit for matching the impedance (usually 50Ω) of the device connected to the supply terminals 5 and 6 with the free space impedance (377Ω).

In the antenna 1F, a wide frequency band is provided even when the magnetic coupling between the inductance elements L1 and L2 is weak, since the inductance element L1 is connected directly to the inductance element L2. In addition, since the other ends of the inductance elements L1 and L2 are connected to the supply terminal 6 via the inductance element L3, the coupling coefficient k between the inductance elements L1 and L2 can be increased. In addition, the addition of an inductance element L3 can realize a wide frequency band, even if the coupling coefficient between the inductance elements L1 and L2 is small. Other operations and advantages of the antenna 1F according to the sixth embodiment of the present invention are basically similar to the operations and advantages of the antenna 1A according to the first embodiment of the present invention.

(Other resonant circuits including LC resonant circuits, Fig.21)

In addition to the first to sixth embodiments of the present invention described above, the resonant circuit constituting the antenna can be implemented in various ways, indicated, for example, by the equivalent circuits shown in Figs. 21 (A) -21 (E). Also with resonant circuits of various methods, small-sized broadband antennas can be implemented.

FIG. 21 (A) shows a resonant circuit including an LC type resonant circuit, which consists of an inductance element L1 and a capacitance element C1, and an LC type resonant circuit, which consists of an inductance element L2 and a capacitance element C2. In the resonance circuit of FIG. 21 (A), the inductance element L1 is connected directly to the inductance element L2, one of the ends of the inductance element L1 is connected to the supply terminal 5, and capacitance elements C1 and C2 are connected to the supply terminal 6.

FIG. 21 (B) shows a resonant circuit including an LC type resonant circuit that consists of an inductance element L1 and a capacitance element C1, and an LC type resonant circuit that consists of an inductance element L2 and a capacitance element C2. In the resonance circuit of FIG. 21 (B), one of the ends of the inductance element L1 is connected to the supply terminal 5, the capacitance element C2 is connected to the inductance elements L1 and L2, and the capacitance element C1 is connected to the other end of the inductance element L2 and the supply terminal 6.

FIG. 21 (C) shows a resonant circuit including an LC type resonant circuit, which consists of an inductance element L1 and a capacitance element C1, and an LC type resonant circuit, which consists of an inductance element L2 and a capacitance element C2. In the resonance circuit of FIG. 21 (C), the inductance element L1 is connected directly to the inductance element L2, the capacitance element C1 is connected to the supply terminal 5, and the capacitance element C2 and the other end of the inductance element L1 are connected to the supply terminal 6.

21 (D) shows a resonant circuit including an LC type resonant circuit, which consists of an inductance element L1 and a capacitance element C1, and an LC type resonant circuit, which consists of an inductance element L2 and a capacitance element C2. In the resonance circuit of FIG. 21 (D), one of the ends of the inductance element L1 is connected to one of the ends of the inductance element L2 through the capacitance element C1, and the other end of the inductance element L1 is connected directly to the other end of the inductance element L2. One end of the inductance element L1 is connected to the supply terminal 5, and the other ends of the inductance elements L1 and L2 are connected to the supply terminal 6.

FIG. 21 (E) shows a resonant circuit including an LC type resonant circuit, which consists of an inductance element L1 and a capacitance element C1, and an LC type resonant circuit, which consists of an inductance element L2 and a capacitance element C2. In the resonance circuit of FIG. 21 (E), the inductance element L1 is connected directly to the inductance element L2, the node between one of the ends of the inductance element L1 and the capacitance element C1 is connected to the supply terminal 5, and the node between the other end L2 of the inductance element and the capacitance element C1 connected to supply terminal 6.

(Seventh Embodiment, FIGS. 22 and 23)

An antenna 1G according to a seventh embodiment of the present invention includes inductance elements L1 and L2 having different inductance values and in-phase magnetically coupled to each other (denoted by mutual inductance M), as shown in an equivalent circuit in FIG. 22. Inductors L1 and L2 are connected in parallel with the supply terminals 5 and 6.

In the antenna 1G having the aforementioned loop configuration, the inductance elements L1 and L2 have different inductance values and are magnetically coupled to each other in phase. The magnetic coupling between the inductance elements L1 and L2 causes the mutual inductance M = L1-L2. According to the modeling performed by the inventor, as shown in FIG. 23, the antenna 1G functions as a radiating element having reflection characteristics in a wide frequency band.

The configuration of the matching circuit with only two inductance elements L1 and L2 achieves reflection characteristics in a wide frequency band as shown in FIG. 23, although the impedance or reactance of the device connected between the supply terminals 5 and 6 is limited by the configuration.

(Eighth Embodiment, FIGS. 24 and 25)

The antenna 1H according to the eighth embodiment of the present invention has a configuration that includes the inductance elements L1 and L2 according to the seventh embodiment of the present invention and the capacitance element C1 connected to one end of the inductance element L1 and the supply terminal 5, as shown in equivalent circuit diagram on Fig.

Also in the 1H antenna having the aforementioned loop configuration, the magnetic coupling between the inductance elements L1 and L2 having different inductance values causes mutual inductance M. According to the simulation performed by the inventor as shown in FIG. 25, the 1H antenna has wideband reflection characteristics frequencies.

(Ninth Embodiment, FIGS. 26 and 27)

Antenna 1I according to the ninth embodiment of the present invention has a configuration that includes inductance elements L1 and L2 according to the seventh embodiment of the present invention, a capacitance element C1 connected to one end of the inductance element L1 and a power terminal 5, and a capacitance element C2 connected with one end of the inductance element L2 and the supply terminal 5, as shown in the equivalent circuit of FIG. 26.

Also in the antenna 1I having the aforementioned loop configuration, the magnetic coupling between the inductance elements L1 and L2 having different inductance values causes the mutual inductance M. According to the simulation performed by the inventor as shown in FIG. 27, the antenna 1I has wideband reflection characteristics frequencies.

(Tenth Embodiment, FIGS. 28-30)

The antenna 1J according to the tenth embodiment of the present invention has a configuration in which a so-called middle tap is provided in the inductance element L1 according to the second embodiment of the present invention and the supply terminal 5 is connected to the middle tap, as shown in the equivalent circuit in FIG. 28. In the antenna 1J, no capacitance element C1 is provided.

In a tenth embodiment of the present invention, the same operations and advantages are provided as in the second embodiment of the present invention. Providing an average tap, the impedance of the space and the impedance of the device connected to the supply terminals 5 and 6 can be matched without reducing the energy of the electromagnetic field. The inductance element L1 is divided into inductances L1a and L1b.

An antenna 1J having the aforementioned loop configuration has, for example, a layered structure shown in FIG. 29. Ceramic sheets 11a-11h made of a dielectric material are laminated, pressed and fired to form an antenna 1J. In particular, the sheet 11a has supply terminals 5 and 6 formed thereon and through-through interconnects 19a and 19b. The sheet 11b has a capacitor electrode 13a formed thereon, a pattern of the connecting wire 15d and through-through interconnects 19c, 19m and 19n. The sheet 11c has a capacitor electrode 14a formed thereon, through-through interconnects 19c, 19m and 19n and a through-through interconnect 19e.

In addition, the sheet 11d has formed on it patterns of connecting wires 15a, 15b and 15c, a through wiring 19n and through wiring 19d, 19g, 19h and 19i. The sheet 11e has wire patterns 16a and 17a formed thereon, through-through interconnects 19g, 19i and 19n and through-through interconnects 19j and 19k. The sheet 11f has the wire patterns 16b and 17b formed thereon and the through wiring 19g, 19i, 19j, 19k and 19n. The sheet 11g has wire patterns 16c and 17c formed thereon and end-to-end interconnects 19g, 19i, 19j and 19k. The sheet 11h has wire patterns 16d and 17d formed thereon.

When the aforementioned sheets 11a-11h are superimposed on each other, the patterns 16a-16d are connected to each other through an inter-connection 19j, forming an inductance element L1 and causing the branch 16c 'of the wire pattern 16c to function as a tap and the branch 16c' to be connected to the supply terminal 5 through the through wiring 19n, the pattern of the connecting wire 15d and the through wiring 19a. In addition, the patterns of wires 17a-17d are connected to each other through an end-to-end interconnect 19k, forming an inductance element L2. The cell element C2 consists of electrodes 13a and 14a.

One end of the inductance element L1 is connected to the capacitor electrode 13a through the through-wire interconnect 19g, the pattern of the connecting wire 15c and the through-wire interconnect 19c. The other end of the inductance element L1 is connected to the supply terminal 6 through the through-wiring 19d, the pattern of the connecting wire 15b and the through-wiring 19m and 19b.

One end of the inductance element L2 is connected to the capacitor electrode 14a via the through-wire interconnect 19i, the pattern of the connecting wire 15a, and the through-wire interconnect 19e. The other end of the inductance element L2 is connected to the supply terminal 6 through the through-wiring 19h, the pattern of the connecting wire 15b and the through-wiring 19m and 19b. The other ends of the inductance elements L1 and L2 are connected by the pattern of the connecting conductor 15b.

In the antenna 1J having the aforementioned configuration of LC type resonant circuits, which include inductance elements L1 and L2 magnetically coupled to each other, resonate, causing the inductance elements L1 and L2 to function as a radiating element. In addition, the connection between the inductance elements L1 and L2 through the capacitance element C2 and the presence of a branch 16c ′ (tap) forms a matching circuit for matching the impedance (usually 50Ω) of the device connected to the supply terminals 5 and 6 with the free space impedance (377Ω).

As a result of the simulation performed by the inventor based on the equivalent circuit shown in FIG. 28, the antenna 1J demonstrated the reflection characteristics shown in FIG. 30.

(Eleventh Embodiment, Figs. 31 and 32)

The antenna 1K according to the eleventh embodiment of the present invention has a configuration in which a capacitance element C1 is added to the antenna 1J according to the tenth embodiment of the present invention, as shown in the equivalent circuit in FIG. 31. In the eleventh embodiment of the present invention, the same operations and advantages are provided as in the tenth embodiment of the present invention. Providing an average tap, the impedance of the space and the impedance of the device connected to the supply terminals 5 and 6, can be selected so that they will not reduce the energy of the electromagnetic field. Adding a capacitance element C1 to the antenna 1J according to the tenth embodiment of the present invention facilitates impedance matching between the supply terminals 5 and 6.

Since the 1K antenna having the aforementioned loop configuration typically has a layered structure similar to that shown in FIGS. 8 and 29, a detailed description of the layered structure of the 1K antenna is omitted in this case. As a result of the simulation performed by the inventor based on the equivalent circuit shown in FIG. 31, the antenna 1K demonstrated the reflection characteristics shown in FIG. 32.

Providing a middle tap, as in the tenth and eleventh embodiments of the present invention, to facilitate matching of the impedance between the supply terminals 5 and 6, provides an increase in reflection, and the bandwidth is expanded in accordance with the increased reflection. In other words, changing the degree of impedance matching changes the bandwidth. Therefore, when setting a constant for each inductance element, in order to achieve the desired bandwidth, it is necessary to take into account the degree of impedance matching.

(Other Embodiments)

The antenna of the present invention is not limited to the embodiments described above, and various changes and modifications may be made within the scope of the present invention.

For example, although the LC resonant circuits according to the above embodiments are configured as lumped parameter loops, the LC resonant circuits can be configured as distributed loops. A layered product including LC resonant circuits, instead of a dielectric material, can be made of insulating material. The laminate may be made, for example, of ceramic or resin.

Industrial applicability

As described above, the present invention is applicable to a surface mount antenna and, in particular, provides advantages in the manufacture of a broadband small-sized antenna.

Claims (11)

1. An antenna including a power terminal and at least two inductance elements having different inductance values,
wherein the inductance elements are used to emit electromagnetic waves, and
moreover, the inductance elements are used as the inductance of the matching circuit to match the impedance of the device intended for connection to the supply terminal, and the impedance of the radiation of free space. 2. The antenna according to claim 1, additionally containing an element of the capacitance,
moreover, the capacitance element and the inductance elements make up many resonant circuits. 3. The antenna, which includes the power terminal and many resonant circuits,
moreover, many resonant circuits are used to emit electromagnetic waves, and
moreover, many resonant circuits are used as a matching circuit to match the impedance of the device intended for connection with the power terminal, and the impedance of the radiation of free space. 4. The antenna according to claim 3, in which each of the plurality of resonant circuits includes a capacitance element and an inductance element. 5. The antenna according to claim 3, in which many resonant circuits are electrically connected to the supply terminal directly or through a concentrated constant capacitance or inductance. 6. The antenna according to claim 3, in which the coupling coefficient between adjacent resonant circuits among the plurality of resonant circuits has a value of at least 0.1. 7. The antenna according to claim 4, in which the inductance element in each resonant circuit consists of patterns of linear electrodes located in the direction of one axis. 8. The antenna according to claim 4, in which the element of the capacitance is electrically connected to the supply terminal. 9. The antenna of claim 8, in which the capacitance element connected to the supply terminal is formed on a multilayer substrate. 10. The antenna according to claim 3, in which many resonant circuits are formed on a multilayer substrate. 11. The antenna, which includes the first and second power terminals and a plurality of resonant circuits, and the antenna contains:
a first LC type resonant circuit comprising a first inductance element and first and second capacitance elements, the first capacitance element being electrically connected to one end of the first inductance element and the second capacitance element electrically connected to the other end of the first inductance element; and
a second LC type resonant circuit comprising a second inductance element and a third and fourth capacitance element, the third capacitance element being electrically connected to one end of the second inductance element and the fourth capacitance element electrically connected to the other end of the second inductance element, the first inductance element being magnetically connected to the second element of inductance,
moreover, one of the ends of the first inductance element is electrically connected to the first supply terminal through the first capacitance element, and its other end is electrically connected to the second supply terminal through the second capacitance element, and
moreover, one of the ends of the second inductance element is electrically connected to the first supply terminal through the third and first capacitance elements, and its other end is electrically connected to the second supply terminal through the fourth and second capacitance elements.

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