KR101491232B1 - Antenna apparatus and feeding structure thereof - Google Patents

Abstract

[0001] The present invention relates to an antenna apparatus and a power supply structure thereof, and more particularly, to a power supply structure including a ground unit, a feed unit for transmitting a signal toward the ground unit, and at least one resonator unit connected to the ground unit, to provide. According to the present invention, it is possible to easily adjust the resonance frequency band of the antenna device without increasing the size of the antenna device.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an antenna device,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a configuration of a communication terminal, and more particularly to an antenna device and a power supply structure thereof.

Generally, a communication terminal has an antenna device for transmitting and receiving electromagnetic waves. Such an antenna apparatus resonates in a specific frequency band and transmits and receives electromagnetic waves in the corresponding frequency band. At this time, when resonance occurs in the corresponding frequency band, the impedance of the antenna device becomes an imaginary number. Then, for the antenna apparatus, the S parameter (S parameter) rapidly decreases in the corresponding frequency band.

To this end, the antenna apparatus has a conducting wire having an electrical length of? / 2 with respect to the wavelength? Corresponding to the desired frequency band. Such an antenna device transmits an electromagnetic wave through a conductor, and as the electromagnetic wave forms a standing wave in the conductor, resonance occurs in the antenna device. At this time, the antenna device has a plurality of wires having different lengths, so that the resonance frequency band can be extended.

However, since the electrical length of the conductor is determined corresponding to the resonance frequency band in the above-described antenna apparatus, the size of the antenna apparatus is determined according to the resonance frequency band. As a result, as the resonance frequency band to be implemented by the antenna device is lowered, the size of the antenna device becomes larger. This becomes more serious as the number of leads in the antenna device increases. That is, the larger the resonance frequency band in the antenna apparatus, the larger the size of the antenna apparatus becomes.

It is therefore an object of the present invention to easily adjust the resonance frequency band in the antenna apparatus. That is, the present invention is intended to adjust the resonance frequency band of the antenna device without increasing the size of the antenna device.

According to an aspect of the present invention, there is provided an antenna device including a radiator, a feeder for supplying a signal to the radiator, a grounding part for grounding the radiator, and at least one resonator part connected to the grounding part And the power supply structure.

At this time, in the antenna device according to the present invention, the resonance adding portion includes a first resonance adding portion disposed between the feeding portion and the grounding portion, and a second resonance adding portion disposed on the opposite side of the first resonance adding portion, 2 resonance adding portion.

In the antenna device according to the present invention, each of the first resonance adding portion and the second resonance adding portion includes at least one reactance element, and the reactance element includes at least one of a capacitive element and an inductive element do.

Here, in the antenna device according to the present invention, the second resonance adding portion may include the capacitive element and the inductive element.

According to another aspect of the present invention, there is provided a power supply structure including a grounding part, a feeding part for transmitting a signal toward the grounding part, and at least one resonating part connected to the grounding part. do.

At this time, in the power supply structure according to the present invention, the resonance adding portion includes a first resonance adding portion disposed between the feeding portion and the ground portion, and a second resonance adding portion disposed on the opposite side of the first resonance adding portion, 2 resonance adding portion.

The antenna device according to the present invention can have a more extended resonance frequency band. That is, the antenna device can operate in a plurality of resonant bands, including at least one resonant adder. As the antenna apparatus includes the reactance element, it is possible to fine-tune the resonance frequency band. At this time, the resonance frequency band can be adjusted by regulating the reactance of the reactance element. As a result, the resonance frequency band of the antenna device can be adjusted without increasing the size of the antenna device. Thus, the antenna device can be miniaturized.

1 is a plan view showing an antenna device according to a first embodiment of the present invention,
Fig. 2 is a circuit diagram showing an equivalent circuit of the feed structure in Fig. 1,
3 is a graph showing the operating characteristics of the antenna device according to the first embodiment of the present invention,
4 is a plan view showing an antenna device according to a second embodiment of the present invention,
Fig. 5 is a circuit diagram showing an equivalent circuit of the power supply structure in Fig. 4,
6 is a graph showing the operating characteristics of the antenna device according to the second embodiment of the present invention,
7 is a plan view showing an antenna device according to a third embodiment of the present invention,
Fig. 8 is a circuit diagram showing an equivalent circuit of the power supply structure in Fig. 7, and
9 is a graph showing the operating characteristics of the antenna device according to the third embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. It should be noted that the same components are denoted by the same reference symbols as possible in the accompanying drawings. Further, the detailed description of known functions and configurations that may obscure the gist of the present invention will be omitted.

1 is a plan view showing an antenna device according to a first embodiment of the present invention. And Fig. 2 is a circuit diagram showing an equivalent circuit of the power supply structure in Fig. 3 is a graph showing the operating characteristics of the antenna device according to the first embodiment of the present invention.

Referring to FIG. 1, the antenna device 100 of the present embodiment includes a driving substrate 110, a grounding member 120, and an antenna element 130.

The driving substrate 110 is provided for feeding and supporting in the antenna device 100. In this case, the driving substrate 110 may be a printed circuit board (PCB). The driving substrate 110 has a flat plate structure. Here, the driving substrate 110 may be a single substrate or a plurality of substrates stacked.

The driving substrate 110 is divided into a ground region 111 and a resonance region 113. Further, a transmission line (not shown) is incorporated in the driving substrate 110. The transmission line is connected to an external device (not shown) of the antenna device 100 via one end. Here, the external device includes a central control unit and an external power source. In addition, the transmission line is exposed to the resonance region 113 via the other end. That is, the transmission line receives a signal from an external device, and transfers the signal from one end to the other end.

The driving substrate 110 also includes a dielectric. Here, the conductivity () of the driving substrate 110 may be 0.02. The permittivity (epsilon) of the driving substrate 110 may be 4.4. In addition, the loss tangent of the driving substrate 110 may be 0.02. At this time, the transmission line is made of a conductive material. Here, the transmission line may include at least one of silver (Ag), palladium (Pd), platinum (Pt), copper (Gu), gold (Au), and nickel (Ni).

The grounding member 120 is provided for grounding at the antenna device 100. [ The grounding member 120 is mounted on the driving substrate 110. At this time, the grounding member 120 is disposed in the grounding region 111. Here, the grounding member 120 may be disposed on at least one of the lower surface and the upper surface of the driving substrate 110. Or the driving substrate 110 is composed of a plurality of substrates, the grounding body 120 may be disposed between the substrates. And the grounding member 120 may have a flat plate structure. Here, the grounding member 120 can cover the grounding region 111 as a whole. Or the grounding member 120 may partially cover the grounding region 111. [

The antenna element 130 is provided for transmitting and receiving signals in the antenna device 100. [ At this time, the antenna element 130 transmits and receives signals in a predetermined resonance frequency band. That is, the antenna element 130 operates in the resonance frequency band to transmit and receive electromagnetic waves. Here, the antenna element 130 can operate as a signal is supplied from the driving substrate 110. Then, the antenna element 130 resonates at a predetermined impedance.

At this time, the resonance frequency band of the antenna element 130 includes a plurality of resonance bands f1, f2, and f3. That is, the resonance frequency band includes the first resonance band f1, the second resonance band f2, and the third resonance band f3. Here, the resonance bands f1, f2, and f3 may be spaced apart from each other in frequency. Accordingly, the resonant frequency band of the antenna element 130 may correspond to multiple frequency bands. Or the resonance bands f1, f2, f3 may be mutually coupled in frequency. Accordingly, the resonant frequency band of the antenna element 130 may correspond to the optical frequency band.

The antenna element 130 is mounted on the driving substrate 110. At this time, the antenna element 130 is disposed in the resonance region 113. Here, the antenna element 130 may be disposed on the upper surface of the driving substrate 110. The antenna element 130 is in contact with the transmission line in the resonance region 113. The antenna element 130 is in contact with the grounding member 120. Here, the antenna element 130 includes a feed structure 140 and a radiator 160.

The feed structure 140 is provided for feeding in the antenna element 130. That is, the feed structure 140 operates the radiator 160. And the feed structure 140, together with the radiator 160, operate. At this time, the power supply structure 140 supplies a signal to the radiator 160. The feed structure 140 also causes the radiator 160 to transmit a signal. Here, the power supply structure 140 includes a feeding part 141, a ground part 143, and two resonance adding parts 145 and 147.

The power feeder 141 supplies a signal to the radiator 160. The power feeder 141 is in contact with the transmission line of the driving substrate 110. At this time, the feed portion 141 contacts the transmission line via one end. Here, one end of the feeding part 141 is defined as a feeding point (FP). For example, the feed point can contact the transmission line at a position close to the grounding member 120. [ In other words, the feed point does not contact the grounding member 120. And the feeding portion 141 extends from the transmission line. At this time, the feed portion 141 extends through the other end. Here, the feeder 141 contacts the radiator 160 through the other end. Thus, the feeder 141 supplies a signal to the radiator 160 from one end to the other end. The power feeder 141 is made of a conductive material. The power feeder 141 may include at least one of silver (Ag), palladium (Pd), platinum (Pt), copper (Gu), gold (Au), and nickel (Ni).

The grounding section 143 grounds the radiator 160. The grounding portion 143 is in contact with the grounding member 120. At this time, the grounding portion 143 contacts the grounding body 120 through one end. Here, one end of the grounding portion 143 is defined as a grounding point. And the grounding portion 143 extends from the grounding body 120. [ At this time, the grounding portion 143 extends through the other end portion. Here, the grounding portion 143 contacts the radiator 160 through the other end. Thereby, the grounding portion 143 grounds the radiator 160 from the other end to the one end. Also, the grounding portion 143 allows the signal to be transmitted from the radiator 160 toward the grounding portion 143.

The grounding unit 143 is connected to the power feeding unit 141. Here, the grounding portion 143 is connected to the feeder 141 via the radiator 160. In other words, the grounding portion 143 is disposed apart from the power feeder 141. That is, the grounding portion 143 is brought into contact with the feeder 141 at a different position from the radiator 160. The grounding portion 143 is made of a conductive material. The grounding unit 143 may include at least one of Ag, Pd, Pt, Cu, Au, and Ni.

The resonance adding sections 145 and 147 are provided to add resonance bands to the resonance frequency band of the antenna element 130. [ The resonance adding sections 145 and 147 are connected to the grounding section 143, respectively. At this time, the resonance adding portions 145 and 147 may be directly connected to the grounding portion 143. Or the resonance adding portions 145 and 147 may be connected to the ground portion 143 through the conductive line. Here, the resonance adding sections 145 and 147 include a first resonance adding section 145 and a second resonance adding section 147. [

The first resonance adding section 145 is connected to the grounding section 143. At this time, the first resonance adding portion 145 is disposed between the feeding portion 141 and the grounding portion 143.

The first resonance adding portion 145 is connected to the grounding member 120. At this time, the first resonance adding portion 145 is connected to the grounding body 120 through one end. Here, the first resonator attachment portion 145 can contact the grounding member 120 through one end. The first resonance adding portion 145 extends from the grounding body 120. At this time, the first resonance adding portion 145 extends through the other end. Here, the first resonance adding portion 145 is connected to the grounding portion 143 through the other end. Also, the first resonance adding portion 145 is grounded from the other end to one end. In addition, the first resonance adding portion 145 includes a conductive material. Here, the first resonator attachment portion 145 may include at least one of Ag, Pd, Pt, Cu, Au, and Ni.

At this time, the first resonance adding portion 145 includes the first reactance element 146. The first reactance element 146 determines the electrical characteristics of the first resonance adding portion 145. And the first reactance element 146 has a predetermined reactance. Here, the first reactance element 146 may be a capacitive element. Also, the first reactance element 146 may have a predetermined capacitance.

In the present embodiment, the first resonance adding portion 145 includes one first reactance element 146, but the present invention is not limited thereto. That is, even if the first resonance adding portion 145 includes a plurality of first reactance elements 146, implementation of the present invention is possible. At this point, the first reactance elements 146 may comprise capacitive elements and inductive elements. For example, at least one of the first reactance elements 146 is a capacitive element, and at least one of the first reactance elements 146 may be an inductive element.

The second resonance adding portion 147 is connected to the grounding portion 143. At this time, the second resonance adding portion 147 is disposed on the opposite side of the first resonance adding portion 145 with respect to the grounding portion 143 as a center. In other words, the grounding portion 143 is disposed between the first resonance adding portion 145 and the second resonance adding portion 147.

The second resonance adding portion 147 is connected to the grounding member 120. At this time, the second resonance adding portion 147 is connected to the grounding body 120 through one end. Here, the second resonator attachment portion 147 can contact the grounding member 120 through one end. The second resonance adding portion 147 extends from the grounding member 120. At this time, the second resonance adding portion 147 extends through the other end. Here, the second resonance adding portion 147 is connected to the ground portion 143 through the other end. And the second resonance adding portion 147 is grounded from the other end to the one end. In addition, the second resonance adding portion 147 includes a conductive material. Here, the second resonator attachment portion 147 may include at least one of Ag, Pd, Pt, Cu, Au, and Ni.

At this time, the second resonance adding portion 147 includes the second reactance elements 148. The second reactance elements 148 determine the electrical characteristics of the second resonant adding portion 147. And each second reactance element 148 has a predetermined reactance. Here, the second reactance elements 148 include a capacitive element and an inductive element. Also, the second reactance elements 148 may have a predetermined capacitance and inductance. That is, any one of the second reactance elements 148 is a capacitive element and can have a capacitance. In addition, the other of the second reactance elements 148 is an inductive element and can have an inductance. For example, in the second resonance adding portion 147, the inductive element may be disposed at a position adjacent to the ground portion 143, and the capacitive element may be disposed at a position adjacent to the ground contact portion 120.

In this embodiment, the second resonance adding portion 147 includes two second reactance elements 148. However, the present invention is not limited thereto. That is, even if the second resonance adding portion 147 includes at least one second reactance element 148, it is possible to implement the present invention. At this time, the second reactance element 148 may be a capacitive element. Or the second resonance adding portion 147 includes at least two second reactance elements 148. [ At this point, the second reactance elements 148 may comprise capacitive elements and inductive elements. For example, at least one of the second reactance elements 148 may be a capacitive element, and at least the other of the second reactance elements 148 may be an inductive element.

That is, the feed structure 140 is designed to have predetermined electrical characteristics. For example, the feed structure 140 can be designed as shown in Fig. Here, the feeding portion 141, the grounding portion 143, and the resonance adding portions 145 and 147 are connected to the conductive line 171. In the first resonance adding portion 145, it is assumed that the first reactance element 146 is the first capacitive element 173. It is also assumed that, in the second resonance adding portion 147, the second reactance elements 148 are the inductive element 174 and the second capacitive element 175. [

At this time, the first capacitive element 173 is connected to the feeding point 172 through the conductive line 171. The inductive element 174 and the second capacitive element 175 are connected in series and are connected to the feed point 172 through the conductive line 171. Here, the inductive element 174 and the second capacitive element 175 are connected in parallel to the first capacitive element 173.

Thereby, in the feed structure 140, three resonant loops are formed: a first resonant loop, a second resonant loop, and a third resonant loop. At this time, when a signal is applied from the driving substrate 110, the power supply structure 140 operates. In the feed structure 140, the feeding part 141 transmits a signal toward the ground part 143. Signals are transmitted from the feeding part 141 to the first resonance adding part 145 and the second resonance adding part 147 in addition to the ground part 143. [

The first resonant loop includes a feeding part 141 and a grounding part 143. And the first resonance loop determines the first resonance band f1 in the resonance frequency band of the antenna element 130. [ At this time, the first resonance band f1 is determined according to the size or shape of the first resonance loop.

The second resonant loop includes a feeding part 141, a first resonating part 145 or a first resonating part 145 and a ground part 143. And the second resonance loop determines the second resonance band f2 in the resonance frequency band of the antenna element 130. [ At this time, the second resonance band f2 is determined according to the size or shape of the second resonance loop and the reactance of the first reactance element 146. [

The third resonant loop includes a feeding part 141, a second resonant adding part 147 or a second resonant adding part 147 and a ground part 143. And the third resonance loop determines the third resonance band f3 in the resonance frequency band of the antenna element 130. [ At this time, the third resonance band f3 is determined according to the size or shape of the third resonance loop and the reactance of the second reactance elements 148. [

The radiator 160 is provided for substantial operation of the antenna element 130 in the resonant frequency band. At this time, when a signal is supplied from the power supply structure 140, the radiator 160 operates in the resonant frequency band. Here, the radiator 150 operates together with the grounding member 120 and the power supply structure 140.

The radiator 160 is connected to the power supply structure 140. At this time, the radiator 160 is connected to the feeding part 141, the grounding part 143 and the resonance adding parts 145 and 147. And the radiator 160 extends on the power supply structure 140. Here, the radiator 160 is connected to the other end of the feed part 141, the other end of the ground part 143, and the other ends of the resonator attachment parts 145 and 147. The radiator 160 is made of a conductive material. Here, the radiator 160 may include at least one of Ag, Pd, Pt, Cu, Au, and Ni.

Accordingly, the antenna apparatus 100 operates in a predetermined resonance frequency band. That is, the antenna apparatus 100 resonates in the first resonance band f1, the second resonance band f2, and the third resonance band f3. For example, the antenna device 100 may have resonance characteristics as shown in Fig.

That is, the antenna apparatus 100 resonates in the first resonance band f1 by the first resonance loop. At this time, the first resonance band f1 is determined according to the first resonance loop. Here, the first resonance band f1 may correspond to approximately 1710 MHz to 2170 MHz. Then, the antenna device 100 resonates in the second resonance band f2 by the second resonance loop. At this time, the second resonance band f2 is determined according to the second resonance loop. Here, the second resonance band f2 may correspond to approximately 698 MHz to 960 MHz. Further, the antenna device 100 resonates in the third resonance band f3 by the third resonance loop. At this time, the third resonance band f3 is determined according to the third resonance loop. Here, the third resonance band f3 may correspond to approximately 2.5 MHz to 2.69 MHz.

4 is a plan view showing an antenna device according to a second embodiment of the present invention. And Fig. 5 is a circuit diagram showing an equivalent circuit of the power supply structure in Fig. 6 is a graph showing operational characteristics of the antenna device according to the second embodiment of the present invention.

Referring to FIG. 4, the antenna device 200 of the present embodiment includes a driving substrate 210, a grounding member 220, and an antenna element 230. The antenna element 230 includes a feed structure 240 and a radiator 260. The feed structure 240 also includes a feed part 241, a ground part 243, and resonance adding parts 245, 247, and 255. In this case, each configuration in this embodiment is similar to the corresponding configuration of the above-described embodiment, and a detailed description thereof will be omitted.

However, in the antenna device 200 of this embodiment, the resonance frequency band of the antenna element 130 includes four resonance bands f1, f2, f3, and f4. That is, the resonance frequency band includes the first resonance band f1, the second resonance band f2, the third resonance band f3, and the fourth resonance band f4. Here, the resonance bands f1, f2, f3, and f4 may be spaced from each other in frequency. Accordingly, the resonant frequency band of the antenna element 230 may correspond to multiple frequency bands. Or resonant bands f1, f2, f3, f4 may be mutually coupled in frequency. Accordingly, the resonant frequency band of the antenna element 230 may correspond to the optical frequency band.

To this end, the antenna element 230 includes three resonant adders 245, 247, 255. Here, the resonance adding units 245, 247, and 255 include the first resonance adding unit 245, the second resonance adding unit 247, and the third resonance adding unit 255. That is, the antenna device 200 of the present embodiment further includes the third resonance adding unit 255. [

The third resonance adding unit 255 is connected to the grounding unit 243. At this time, the third resonance adding portion 255 is disposed on the opposite side of the first resonance adding portion 245 and the second resonance adding portion 247 with the feeder 241 as the center. In other words, the feeding portion 241 is disposed between the first resonance adding portion 245 and the second resonance adding portion 247 and the third resonance adding portion 255.

The third resonance adding unit 255 is connected to the grounding member 220. At this time, the third resonance adding part 255 is connected to the grounding body 220 through one end. Here, the third resonance adding part 255 can contact the grounding body 220 through one end. The third resonance adding portion 255 extends from the grounding body 220. At this time, the third resonance adding portion 255 extends through the other end. Here, the third resonance adding portion 255 is connected to the ground portion 243 through the other end. And the third resonance adding portion 255 is grounded from the other end to one end. In addition, the third resonance adding portion 255 includes a conductive material. The third resonance adding unit 255 may include at least one of Ag, Pd, Pt, Cu, Au, and Ni.

At this time, the third resonance adding portion 255 includes the third reactance element 256. [ The third reactance element 256 determines the electrical characteristics of the third resonance adding portion 255. And the third reactance element 256 has a predetermined reactance. Here, the third reactance element 256 may be a capacitive element. Also, the third reactance element 256 may have a predetermined capacitance.

In this embodiment, the third resonance adding unit 255 includes one third reactance element 256. However, the present invention is not limited thereto. That is, even if the third resonance adding unit 255 includes a plurality of third reactance elements 256, the present invention can be implemented. At this time, the third reactance elements 256 may include a capacitive element and an inductive element. For example, at least one of the third reactance elements 256 may be a capacitive element, and at least the other of the third reactance elements 256 may be an inductive element.

That is, the feed structure 240 is designed to have predetermined electrical characteristics. For example, the feed structure 240 can be designed as shown in Fig. Here, the feeding portion 241, the ground portion 243, and the resonance adding portions 245, 247, and 255 are connected to the conductive line 271. In the first resonance adding portion 245, it is assumed that the first reactance element 246 is the first capacitive element 273. It is also assumed that, in the second resonance adding portion 247, the second reactance elements 248 are the inductive element 274 and the second capacitive element 275. In addition, in the third resonance adding portion 255, it is assumed that the third reactance element 256 is the third capacitive element 276. [

At this time, the first capacitive element 273 is connected to the feeding point 272 via the conductive line 271. The inductive element 274 and the second capacitive element 275 are connected in series and connected to the feeding point 272 through the conductive line 271. Here, the inductive element 274 and the second capacitive element 275 are connected in parallel to the first capacitive element 273. And the third capacitive element 276 is connected to the feeding point 272 via the conductive line 271. [ Here, the third capacitive element 276 is connected in parallel to the first capacitive element 273. In addition, a third capacitive element 276 is connected in parallel to the inductive element 274 and the second capacitive element 275.

Thus, in the feed structure 240 of the present embodiment, four resonance loops are formed: a first resonance loop, a second resonance loop, a third resonance loop, and a fourth resonance loop. At this time, when a signal is applied from the driving substrate 210, the power supply structure 240 operates. In the feed structure 240, the feeding part 241 transmits a signal toward the ground part 243. Signals are transmitted from the feeding portion 241 to the first resonance adding portion 245, the second resonance adding portion 247, and the third resonance adding portion 255, as well as the grounding portion 243.

The first resonant loop includes a feeding part 241 and a ground part 243. And the first resonance loop determines the first resonance band f1 in the resonance frequency band of the antenna element 230. [ At this time, the first resonance band f1 is determined according to the size or shape of the first resonance loop.

The second resonant loop includes a feeding part 241, a first resonance adding part 245 or a first resonating adding part 245 and a ground part 243. And the second resonance loop determines the second resonance band f2 in the resonance frequency band of the antenna element 230. [ At this time, the second resonance band f2 is determined according to the size or shape of the second resonance loop and the reactance of the first reactance element 246. [

The third resonant loop includes a feeding part 241, a second resonance adding part 247 or a second resonating adding part 247 and a ground part 243. And the third resonance loop determines the third resonance band f3 in the resonance frequency band of the antenna element 230. [ At this time, the third resonance band f3 is determined according to the size or shape of the third resonance loop and the reactance of the second reactance elements 248. [

The fourth resonance loop includes a feeding part 241, a third resonance adding part 255 or a third resonance adding part 255 and a ground part 243. And the third resonance loop determines the fourth resonance band f4 in the resonance frequency band of the antenna element 230. [ At this time, the fourth resonance band f4 is determined according to the size or shape of the fourth resonance loop and the reactance of the third reactance element 256. [

Accordingly, the antenna device 200 operates in a predetermined resonance frequency band. That is, the antenna device 200 resonates in the first resonance band f1, the second resonance band f2, the third resonance band f3, and the fourth resonance band f4. For example, the antenna device 200 may have a resonance characteristic as shown in Fig.

That is, the antenna device 200 resonates in the first resonance band f1 by the first resonance loop. At this time, the first resonance band f1 is determined according to the first resonance loop. Then, the antenna device 200 resonates in the second resonance band f2 by the second resonance loop. At this time, the second resonance band f2 is determined according to the second resonance loop. Further, the antenna device 200 resonates in the third resonance band f3 by the third resonance loop. At this time, the third resonance band f3 is determined according to the third resonance loop. In addition, the antenna device 200 resonates in the fourth resonance band f4 by the fourth resonance loop. At this time, the fourth resonance band f4 is determined according to the fourth resonance loop.

7 is a plan view showing an antenna device according to a third embodiment of the present invention. And Fig. 8 is a circuit diagram showing an equivalent circuit of the power supply structure in Fig. 9 is a graph showing operational characteristics of the antenna device according to the third embodiment of the present invention.

Referring to FIG. 7, the antenna device 300 of the present embodiment includes a driving substrate 310, a grounding member 320, and an antenna element 330. The antenna element 330 includes a feed structure 340 and a radiator 360. The feed structure 340 also includes a feed part 341, ground parts 343 and 353 and resonance parts 345, 347, 355 and 357. In this case, each configuration in this embodiment is similar to the corresponding configuration of the above-described embodiment, and a detailed description thereof will be omitted.

However, in the antenna device 300 of this embodiment, the resonance frequency band of the antenna element 330 includes five resonance bands f1, f2, f3, f4, and f5. That is, the resonance frequency band includes the first resonance band f1, the second resonance band f2, the third resonance band f3, the fourth resonance band f4, and the fifth resonance band f5. Here, the resonance bands f1, f2, f3, f4, and f5 may be spaced from each other in frequency. Accordingly, the resonant frequency band of the antenna element 330 may correspond to multiple frequency bands. Or the resonance bands f1, f2, f3, f4, f5 may be mutually coupled in frequency. Accordingly, the resonant frequency band of the antenna element 330 may correspond to the optical frequency band.

To this end, the antenna element 330 includes two grounding portions 343, 353 and four resonance adding portions 345, 347, 355, 357. Here, the grounding parts 343 and 353 include a first grounding part 343 and a second grounding part 353. The resonance adding sections 345, 347, 355 and 357 are connected to the first resonance adding section 345, the second resonance adding section 347, the third resonance adding section 355 and the fourth resonance adding section 357 . That is, the antenna device 300 of the present embodiment further includes a second ground portion 353, a third resonance adding portion 355, and a fourth resonance adding portion 357.

The second grounding portion 353 is disposed on the opposite side of the first grounding portion 343 with respect to the feeding portion 341 as a center. In other words, the feeding portion 341 is disposed between the first grounding portion 343 and the second grounding portion 353. The second grounding unit 353 grounds the radiator 360. The second grounding portion 353 contacts the grounding body 320. At this time, the second grounding portion 353 contacts the grounding body 320 through one end. Here, one end of the second grounding portion 353 is defined as a grounding point. And the second grounding portion 353 extends from the grounding body 320. [ At this time, the second grounding portion 353 extends through the other end. Here, the second grounding portion 353 contacts the radiator 360 through the other end. Thereby, the second grounding portion 353 grounds the radiator 360 from the other end to the one end.

The second grounding unit 353 is connected to the power feeding unit 341. Here, the second grounding part 353 is connected to the feeding part 341 through the radiator 360. In other words, the second grounding portion 353 is disposed apart from the power feeding portion 341. [ That is, the second grounding portion 353 is brought into contact with the radiator 360 at a different position from the feed portion 341. The second grounding portion 353 is made of a conductive material. The second ground unit 353 may include at least one of silver (Ag), palladium (Pd), platinum (Pt), copper (Gu), gold (Au), and nickel (Ni).

And the third resonance adding portion 355 is connected to the second grounding portion 353. At this time, the third resonance adding portion 355 is arranged on the opposite side of the first resonance adding portion 345 and the second resonance adding portion 347, with the feeder 341 as the center. In other words, the feeding portion 341 is disposed between the first resonance adding portion 345 and the second resonance adding portion 347 and the third resonance adding portion 355.

The third resonance adding portion 355 is connected to the grounding body 320. At this time, the third resonance adding portion 355 is connected to the grounding body 320 through one end. Here, the third resonator attachment portion 355 can contact the grounding member 320 through one end. The third resonance adding portion 355 extends from the grounding body 320. [ At this time, the third resonance adding portion 355 extends through the other end. Here, the third resonance adding portion 355 is connected to the second grounding portion 353 through the other end. The third resonance adding portion 355 is grounded from the other end to one end. In addition, the third resonance adding portion 355 includes a conductive material. The third resonator 355 may include at least one of Ag, Pd, Pt, Cu, Au, and Ni.

At this time, the third resonance adding portion 355 includes the third reactance element 356. [ The third reactance element 356 determines the electrical characteristics of the third resonance adding portion 355. And the third reactance element 356 has a predetermined reactance. Here, the third reactance element 356 may be a capacitive element. The third reactance element 356 may have a predetermined capacitance.

In the present embodiment, the third resonance adding unit 355 includes one third reactance element 356. However, the present invention is not limited thereto. That is, even if the third resonance adding portion 355 includes a plurality of third reactance elements 356, implementation of the present invention is possible. At this point, the third reactance elements 356 may comprise capacitive elements and inductive elements. For example, at least one of the third reactance elements 356 may be a capacitive element, and at least the other of the third reactance elements 356 may be an inductive element.

And the fourth resonance adding portion 357 is connected to the second grounding portion 353. At this time, the fourth resonance adding portion 357 is disposed on the opposite side of the third resonance adding portion 355, with the second grounding portion 353 as the center. In other words, the second grounding portion 353 is disposed between the third resonance adding portion 355 and the fourth resonance adding portion 357.

The fourth resonance adding portion 357 is connected to the grounding body 320. At this time, the fourth resonance adding portion 357 is connected to the grounding body 320 through one end. Here, the fourth resonance adding portion 357 can contact the grounding body 320 through one end. The fourth resonance adding portion 357 extends from the grounding body 320. At this time, the fourth resonance adding portion 357 extends through the other end portion. Here, the fourth resonance adding portion 357 is connected to the second grounding portion 353 through the other end. The fourth resonance adding portion 357 is grounded from the other end to the one end. In addition, the fourth resonance adding portion 357 includes a conductive material. The fourth resonator 357 may include at least one of Ag, Pd, Pt, Cu, Au, and Ni.

At this time, the fourth resonance adding section 357 includes the fourth reactance elements 358. The fourth reactance elements 358 determine the electrical characteristics of the fourth resonance adding portion 357. [ And each fourth reactance element 358 has a predetermined reactance. Here, the fourth reactance elements 358 include a capacitive element and an inductive element. The fourth reactance elements 358 may also have a predetermined capacitance and inductance. That is, any one of the fourth reactance elements 358 is a capacitive element and can have a capacitance. In addition, the other of the fourth reactance elements 358 is an inductive element and can have an inductance. For example, in the fourth resonance adding portion 357, an inductive element is disposed at a position adjacent to the second ground portion 353, and a capacitive element is disposed at a position adjacent to the grounding body 320. [

In this embodiment, the fourth resonance adding unit 357 includes two fourth reactance elements 358. However, the present invention is not limited thereto. That is, the fourth resonance adding portion 357 includes at least one fourth reactance element 358, the present invention is possible. At this time, the fourth reactance element 358 may be a capacitive element. Or the fourth resonance adding section 357 includes at least two fourth reactance elements 358. [ At this point, the fourth reactance elements 358 may comprise capacitive elements and inductive elements. For example, at least one of the fourth reactance elements 358 may be a capacitive element, and at least the other of the fourth reactance elements 358 may be an inductive element.

That is, the feed structure 340 is designed to have predetermined electrical characteristics. For example, the feed structure 340 may be designed as shown in Fig. The feeding part 341, the grounding parts 343 and 353 and the resonance adding parts 345, 347, 355 and 357 are connected to the conductive line 371. In the first resonance adding portion 345, it is assumed that the first reactance element 346 is the first capacitive element 373. It is also assumed that, in the second resonance adding portion 347, the second reactance elements 348 are the first inductive element 374 and the second capacitive element 375. Further, in the third resonance adding portion 355, it is assumed that the third reactance element 356 is the third capacitive element 376. [ In addition, in the fourth resonance adding portion 357, it is assumed that the fourth reactance elements 358 are the second inductive element 377 and the fourth capacitive element 378.

At this time, the first capacitive element 373 is connected to the feeding point 372 through the conductive line 371. The first inductive element 374 and the second capacitive element 375 are connected in series and are connected to the feed point 372 through the conductive line 371. Here, the first inductive element 374 and the second capacitive element 375 are connected in parallel to the first capacitive element 373. And the third capacitive element 376 is connected to the feeding point 372 through the conductive line 371. [ Here, the third capacitive element 376 is connected in parallel to the first capacitive element 373. In addition, a third capacitive element 376 is connected in parallel to the first inductive element 374 and the second capacitive element 375. In addition, the second inductive element 377 and the fourth capacitive element 378 are connected in series and connected to the feed point 372 via the conductive line 371. Here, the second inductive element 377 and the fourth capacitive element 378 are connected in parallel to the third capacitive element 376.

Thus, in the feed structure 340 of the present embodiment, five resonance loops are formed: a first resonance loop, a second resonance loop, a third resonance loop, a fourth resonance loop, and a fifth resonance loop. At this time, when a signal is applied from the driving substrate 310, the power supply structure 340 operates. In the feed structure 340, the feeding part 341 transmits a signal toward the first ground part 343 and the second ground part 353. Here, not only the first ground portion 243 and the second ground portion 353 but also the first resonance adding portion 345, the second resonance adding portion 347, the third resonance adding portion 355 And the fourth resonance adding unit 357, respectively.

The first resonant loop includes a feeding part 341 and a first grounding part 343. And the first resonance loop determines the first resonance band f1 in the resonance frequency band of the antenna element 330. [ At this time, the first resonance band f1 is determined according to the size or shape of the first resonance loop.

The second resonant loop includes a feeding part 341, a first resonant adding part 345 or a first resonant adding part 345 and a first ground part 343. And the second resonance loop determines the second resonance band f2 in the resonance frequency band of the antenna element 330. [ At this time, the second resonance band f2 is determined according to the size or shape of the second resonance loop and the reactance of the first reactance element 346. [

The third resonant loop includes a feeding part 341, a second resonant adding part 347 or a second resonant adding part 347 and a first ground part 343. And the third resonance loop determines the third resonance band f3 in the resonance frequency band of the antenna element 330. [ At this time, the third resonance band f3 is determined according to the size or shape of the third resonance loop and the reactance of the second reactance elements 348. [

The fourth resonance loop includes the feed part 341, the third resonance adding part 355 or the third resonance adding part 355 and the second ground part 353. And the third resonance loop determines the fourth resonance band f4 in the resonance frequency band of the antenna element 330. [ At this time, the fourth resonance band f4 is determined according to the size or shape of the fourth resonance loop and the reactance of the third reactance element 356. [

The fifth resonance loop includes a feed part 341, a fourth resonance adding part 357 or a fourth resonance adding part 357 and a second ground part 353. And the fourth resonance loop determines the fifth resonance band f5 in the resonance frequency band of the antenna element 330. [ At this time, the fifth resonance band f5 is determined according to the size or shape of the fifth resonance loop and the reactance of the fourth reactance elements 358. [

Accordingly, the antenna apparatus 300 operates in a predetermined resonance frequency band. That is, the antenna device 300 resonates in the first resonance band f1, the second resonance band f2, the third resonance band f3, the fourth resonance band f4, and the fifth resonance band f5. For example, the antenna device 300 may have resonance characteristics as shown in Fig.

That is, the antenna device 300 resonates in the first resonance band f1 by the first resonance loop. At this time, the first resonance band f1 is determined according to the first resonance loop. Then, the antenna device 300 resonates in the second resonance band f2 by the second resonance loop. At this time, the second resonance band f2 is determined according to the second resonance loop. Further, the antenna device 300 resonates in the third resonance band f3 by the third resonance loop. At this time, the third resonance band f3 is determined according to the third resonance loop. In addition, the antenna device 300 resonates in the fourth resonance band f4 by the fourth resonance loop. At this time, the fourth resonance band f4 is determined according to the fourth resonance loop. In addition, the antenna device 300 resonates in the fifth resonance band f5 by the fifth resonance loop. At this time, the fifth resonance band f5 is determined according to the fifth resonance loop.

Meanwhile, although the antenna elements 130, 230, and 330 are mounted on the driving substrates 110, 210, and 310 in the above-described embodiments, the present invention is not limited thereto. That is, even if at least a part of the antenna elements 130, 230, and 330 are not mounted on the driving substrates 110, 210, and 310, the present invention can be implemented.

For example, when the antenna devices 100, 200, 300 are mounted on a communication terminal (not shown), the antenna elements 130, 230, 330 can be attached to the inner surface at the outer case of the communication terminal. The driving boards 110, 210, and 310 may be disposed in the inner space of the outer case of the communication terminal.

210, 310 with the antenna elements 130, 230, 330 mounted on a mounting member (not shown) such as a carrier. In other words, a mounting member can be interposed between the driving substrate 110, 210, 310 and the antenna element 130, 230, 330. [ For example, at least a portion of the antenna elements 130, 230, 330 may be mounted to the mounting member. Here, when a part of the antenna elements 130, 230 and 330 is mounted on the mounting member, the rest of the antenna elements 130, 230 and 330 may be directly mounted on the driving boards 110, 210 and 310.

At this time, the antenna elements 130, 230 and 330 can contact the transmission lines of the driving substrates 110, 210 and 310. Here, the feeding parts 141, 241, and 341 of the antenna elements 130, 230, and 330 can contact the transmission line through one end. The antenna elements 130, 230, and 330 may be in contact with the grounding members 120, 220, and 320, respectively. Here, the grounding portions 143, 243, and 343 of the antenna elements 130, 230, and 330 can contact the grounding members 120, 220, and 320 through one end.

According to the present invention, the resonance frequency bands of the antenna devices 100, 200, and 300 can be easily adjusted. That is, the antenna devices 100, 200, and 300 may operate in a plurality of resonance bands including the resonance adding parts 145, 147, 245, 247, 255, 345, 347, 355, and 357. As the antenna devices 100, 200 and 300 include the reactance elements 146, 148, 246, 248, 256, 346, 348, 356 and 358, fine tuning of the resonance frequency band is possible. At this time, the reactance of the reactance elements 146, 148, 246, 248, 256, 346, 348, 356, 358 can be adjusted to adjust the resonance frequency band. Therefore, the resonance frequency bands of the antenna devices 100, 200, and 300 can be adjusted without increasing the size of the antenna devices 100, 200, and 300. Accordingly, miniaturization of the antenna devices 100, 200, and 300 can be realized.

It should be noted that the embodiments of the present invention disclosed in the present specification and drawings are only illustrative of the present invention in order to facilitate the understanding of the present invention and are not intended to limit the scope of the present invention. That is, it will be apparent to those skilled in the art that other modifications based on the technical idea of the present invention are possible.

100, 200, 300: antenna device
110, 210, and 310:
120, 220, 320:
130, 230, 330: antenna element
140, 240, 340: feeding structure
141, 241, 341:
143, 243, 343, and 353:
145, 147, 245, 247, 255, 345, 347, 355, 357:
146, 148, 246, 248, 256, 346, 348, 356, 358: reactance element
160, 260, 360: Emitter

Claims (16)

The radiator,
And a power supply structure including a feed part for supplying a signal to the radiator, a ground part for grounding the radiator, and at least one resonator part connected to the ground part,
The resonance adding portion includes a first resonance adding portion disposed between the feeding portion and the ground portion and having a capacitive element,
And a second resonator part including a plurality of reactance elements connected in series and disposed on the opposite side of the first resonator part with respect to the ground part. The power supply structure according to claim 1,
A first resonant loop including the feeding portion and the ground portion, the first resonant loop determining a first resonant band;
A second resonant loop including the feed part, the first resonance adding part or the first resonance adding part and the ground part, and determining a second resonance band; And
And a third resonant loop including the feeding part, the second resonant adding part or the second resonant adding part and the ground part, and determining a third resonant band. 3. The method of claim 2,
Wherein the first resonance band is determined according to a size or a shape of the first resonance loop. 3. The method of claim 2,
Wherein the second resonance band is determined according to the size or shape of the second resonance loop. 3. The method of claim 2,
Wherein the third resonance band is determined according to a size or a shape of the third resonance loop. 2. The semiconductor device according to claim 1, wherein the reactance element comprises:
Wherein the antenna element comprises a capacitive element and an inductive element. The power supply structure according to claim 1,
Further comprising a third resonance attaching portion disposed on the opposite side of the first resonance adding portion with respect to the feeding portion. 8. The power supply structure according to claim 7,
Further comprising: a fourth grounding part connected to the third resonating part; and a fourth resonating part disposed on the opposite side of the third resonating part from the second grounding part. 9. The resonator according to claim 8, wherein the third resonance adding portion and the fourth resonance adding portion comprise:
And at least one reactance element. 10. The reactance element according to claim 9,
Wherein the antenna element includes at least one of a capacitive element and an inductive element. 11. The resonator according to claim 10,
Wherein the antenna element comprises a capacitive element and an inductive element. A grounding portion,
A feeding part connected to the grounding part,
And at least one resonator attachment portion connected to the ground portion,
Wherein the resonance adding portion includes a first resonance adding portion disposed between the feeding portion and the grounding portion and having a capacitive element and a plurality of second resonance adding portions disposed on the opposite side of the first resonance adding portion with respect to the grounding portion, And a second resonance adding portion including a reactance element. delete delete 13. The method of claim 12,
Further comprising a third resonance attaching portion disposed on the opposite side of the resonance receiving portion with respect to the feeding portion. 16. The method of claim 15,
A second grounding portion connected to the third resonance adding portion,
Further comprising a fourth resonance attaching portion disposed on the opposite side of the third resonating portion with respect to the second grounding portion.

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