KR101449260B1 - Antenna apparatus and feeding structure thereof - Google Patents

Abstract

The present invention relates to an antenna device and a power supply structure thereof, and more particularly to an antenna device and a power supply structure therefor. The antenna device includes a resonance part including a feeding part supplying a signal and a grounding part connected to the feeding part, a resonance adding part disposed between the feeding part and the grounding part, And a regulator for regulating a position where a signal is outputted from the resonance part, and an antenna device having the same. According to the present invention, it is possible to easily adjust the resonance frequency band while maintaining the operating performance of the antenna device and the power supply structure by using the frequency controller.

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 is provided with an antenna device for transmitting and receiving an electromagnetic wave. 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 and a power supply structure for driving the radiator, wherein the power supply structure includes a power feeder for supplying a signal to the radiator, And a control unit connected to the power supply unit and adjusting a position where the radiator and the resonance unit are connected to each other. The resonance unit includes a resonance unit including a resonance unit, a resonance unit, and a ground unit.

At this time, in the antenna device according to the present invention, the adjusting portion includes a plurality of connecting portions arranged to be spaced apart from each other, and electrically connects any one of the connecting portions to the feeding portion.

Here, in the antenna device according to the present invention, the connecting portions are arranged in parallel to each other from the inside to the outside of the resonating portion.

And, in the antenna device according to the present invention, the radiator includes a plurality of contact portions individually contacting the connecting portions.

In addition, in the antenna device according to the present invention, the adjusting portion adjusts the size of a resonance loop formed in the feed structure.

According to another aspect of the present invention, there is provided a power supply structure including a resonance part including a feed part supplying a signal and a ground part connected to the feed part, a resonance part disposed between the feed part and the ground, And an adjusting unit connected to the feeding unit and adjusting a position at which the signal is output from the resonating unit.

At this time, in the power supply structure according to the present invention, the adjusting portion includes a plurality of connecting portions arranged to be spaced apart from each other, and connects any one of the connecting portions to the feeding portion.

Here, in the power supply structure according to the present invention, the connection portions are arranged in parallel to each other from the inner side to the outer side of the resonance portion.

In the feed structure according to the present invention, the adjustment unit adjusts the size of at least one of the resonance loops formed in the feed structure.

The antenna device and the power supply structure according to the present invention can easily adjust the resonance frequency band using the adjusting part. At this time, the resonance frequency band can be adjusted while the operation performance of the antenna device and the power supply structure is maintained according to the switching operation of the regulating part. Accordingly, the antenna apparatus can selectively connect to a plurality of communication networks. That is, the antenna apparatus can adjust the resonance frequency band and connect to the desired communication network. In addition, even if the physical length of the radiator or the feed structure does not increase in the antenna apparatus, the resonance frequency band can be adjusted. Therefore, the resonance frequency band can be adjusted without increasing the size of the antenna device.

1 is a block diagram showing a communication terminal to which the present invention is applied;
FIG. 2 is a perspective view illustrating the antenna device according to the first embodiment of the present invention,
Fig. 3 is a plan view showing a part of the configuration of the antenna device in Fig. 2,
Fig. 4 is a circuit diagram showing an equivalent circuit of the power supply structure in Fig. 2,
5 is a graph for explaining operational characteristics of the antenna device according to the first embodiment of the present invention,
6 is a plan view showing a modified example of the antenna device according to the first embodiment of the present invention,
7 is a perspective view of the antenna device according to the second embodiment of the present invention,
8 is a plan view showing a part of the configuration of the antenna device in Fig. 7, and Fig.
9 is a plan view showing a modification of the antenna device according to the second 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 block diagram showing a communication terminal to which the present invention is applied.

1, the communication terminal 10 of the present embodiment includes an antenna device 20, a wireless communication unit 30, a control unit 40, and a memory 50. As shown in FIG.

The antenna device 20 performs the wireless transmission / reception function of the communication terminal 10. That is, the antenna apparatus 20 transmits a transmission signal wirelessly and receives a reception signal wirelessly. At this time, the antenna device 20 operates in the resonance frequency band. And the antenna device 20 connects to a plurality of communication networks. Here, the antenna device 20 selectively connects to any of the communication networks. To this end, the antenna device 20 adjusts the resonance frequency band corresponding to each communication network. That is, the antenna device 20 can be connected to any one of the communication networks through the resonance frequency band.

The wireless communication unit (30) performs the wireless processing function of the communication terminal (10). The wireless communication unit 30 includes a wireless transmission unit and a wireless reception unit. The radio transmission unit processes the transmission signal and transmits it to the antenna apparatus 20. Here, the radio transmission unit can up-convert and amplify the frequency of the transmission signal. The wireless receiving unit receives the received signal from the antenna device 20 and processes it. Here, the radio receiver can perform low-noise amplification of the received signal and down-convert the frequency.

The controller 40 controls the overall operation of the communication terminal 10. The control unit 40 includes a data processing unit. The data processing unit includes a transmitter for encoding and modulating a transmission signal, and a receiver for demodulating and decoding the reception signal. At this time, the data processing unit may be composed of a modem (MODEM) and a codec (CODEC). Here, the codec may include a data codec for processing packet data and an audio codec for processing an audio signal such as voice. The control unit 40 determines one of the plurality of communication networks. Further, the control unit 40 controls the antenna device 20 to operate in any one of a plurality of resonance frequency bands. Accordingly, the control unit 40 connects to any one of the communication networks through the antenna device 20 and performs communication.

The memory 50 includes a program memory and a data memory. The program memory stores programs for controlling the general operation of the communication terminal 10. [ At this time, the program memory stores programs for controlling the antenna device 20. The data memory stores data generated during the execution of the programs. The memory 50 may store the communication networks and the resonance frequency bands corresponding to each other.

2 and 3 are views showing an antenna device according to a first embodiment of the present invention. FIG. 2 is a perspective view of the antenna device according to the first embodiment of the present invention, and FIG. 3 is a plan view showing a part of the antenna device in FIG. And Fig. 4 is a circuit diagram showing an equivalent circuit of the power supply structure in Fig. 5 is a graph illustrating operational characteristics of the antenna device according to the first embodiment of the present invention. 6 is a plan view showing a modified example of the antenna device according to the first embodiment of the present invention.

2 and 3, the antenna device 100 of the present embodiment includes a driving substrate 110, a grounding member 120, an antenna element 130, and a mounting member 180.

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.

A transmission line (not shown) is incorporated in the driving substrate 110. The transmission line is connected to the control unit (40 in Fig. 1) via one end. The transmission line is exposed through the other end. That is, the transmission line receives a signal from the control unit (40 in FIG. 1) and transmits the signal from one end to the other end. In this case, the driving substrate 110 may be divided into a ground region 111 and an antenna region 113. Here, the transmission line can be exposed in the antenna region 113.

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. [ Such a grounding member 120 is formed in a part or the whole area of the driving substrate 110. At this time, the grounding member 120 may be 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.

The antenna element 130 is provided for transmitting and receiving signals in the antenna device 100. [ At this time, the antenna element 130 is connected to any one of the communication networks under the control of the control unit (40 in FIG. 1). Here, the antenna element 130 corresponds to one of the communication networks and adjusts the resonance frequency band. That is, the antenna element 130 connects to any one of the communication networks through the resonance frequency band. The antenna element 130 transmits and receives signals. In other words, the antenna element 130 operates as a signal is supplied from the driving substrate 110. Here, 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. That is, the resonance frequency band includes the first resonance band and the second resonance band. Here, the first resonance band may correspond to a relatively low frequency as compared with the second resonance band. In other words, the second resonance band can correspond to a relatively high frequency as compared with the first resonance band. And the first resonance band and the second resonance band may be spaced from each other in the frequency domain. Accordingly, the resonant frequency band of the antenna element 130 may correspond to multiple frequency bands. Or the first resonance band and the second resonance band may be mutually coupled in the frequency domain. Accordingly, the resonant frequency band of the antenna element 130 may correspond to the optical frequency band.

The antenna element 130 is disposed on the driving substrate 110. At this time, the antenna element 130 may be disposed on the upper portion of the driving substrate 110. Here, the antenna element 130 may be disposed in the antenna region 113. Then, the antenna element 130 contacts the transmission line. The antenna element 130 is in contact with the grounding member 120. Here, the antenna element 130 includes the feed structure 140 and the radiator 170.

The feed structure 140 is provided for feeding a signal at the antenna element 130. That is, the feed structure 140 operates the radiator 170. And the feed structure 140, together with the radiator 170, operate. At this time, the power supply structure 140 supplies a signal to the radiator 170.

The power supply structure 140 is disposed on the driving substrate 110. At this time, the power supply structure 140 may be attached to the upper surface of the driving substrate 110. Then, the feed structure 140 contacts the transmission line. The power supply structure 140 also contacts the grounding member 120. As a result, a signal flows into the grounding member 120 from the power supply structure 140. Here, the power supply structure 140 includes a resonator 141, a resonator 151, and an adjuster 155.

The resonance section 141 determines the first resonance band in the resonance frequency band of the antenna element 130. [ The resonance unit 141 includes a feed unit 143, a ground unit 145, a first connection unit 147, and a second connection unit 149. At this time, the resonance unit 141 is formed by connecting the feed unit 143, the ground unit 145, the first connection unit 147, and the second connection unit 149.

The feeding part 143 supplies a signal to the resonating part 141. That is, the feeding portion 143 contacts the transmission line of the driving substrate 110. At this time, the feed portion 143 contacts the transmission line via one end. Here, one end of the feeding part 143 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. As a result, a signal is supplied from the control unit (40 in FIG. 1) to the power feeder 143. And the feeding portion 143 extends from the transmission line. At this time, the feed portion 143 extends through the other end. Thereby, the feeding part 143 supplies the signal from one end to the other end. The feeding part 143 is made of a conductive material. The power feeder 143 may include at least one of Ag, Pd, Pt, Cu, Au, and Ni.

The grounding unit 145 grounds the resonating unit 141. That is, the grounding part 145 contacts the grounding body 120. At this time, the grounding part 145 comes into contact with the grounding body 120 through one end. Here, one end of the grounding portion 145 is defined as a grounding point. And the grounding portion 145 extends from the grounding body 120. [ At this time, the grounding portion 145 extends through the other end portion. Here, the grounding portion 145 contacts the power feeder 143 through the other end. Thereby, the grounding portion 145 is grounded. The grounding portion 145 is made of a conductive material. The grounding part 145 may include at least one of Ag, Pd, Pt, Cu, Au, and Ni.

The first connection part 147 and the second connection part 149 connect the feed part 143 and the ground part 145. The first connection part 147 and the second connection part 149 are connected to each other. The first connection part 147 is connected to the power supply part 143 and the second connection part 149 is connected to the ground part 145. Accordingly, the first connection part 147 and the second connection part 149 transmit signals from the power supply part 143 to the ground part 145. The first connection part 147 and the second connection part 149 are made of a conductive material. The first connection part 147 and the second connection part 149 include at least one of Ag, Pd, Pt, Cu, Au, and Ni. can do.

At this time, the first connection part 147 contacts the feed part 143 via one end. Here, the first connection portion 147 is in contact with the other end of the feed portion 143. The first connection part 147 extends from the power feed part 143. Here, the first connection portion 147 extends through the other end portion. On the other hand, the second connection part 149 contacts the first connection part 147 through one end. Here, the second connection portion 149 is in contact with the other end of the first connection portion 147. The second connection portion 149 extends from the first connection portion 147. Here, the second connection portion 149 extends through the other end portion. In addition, the second connecting portion 149 contacts the grounding portion 145. Here, the second connection portion 149 contacts the other end of the ground portion 145 through the other end. Thus, the first connection part 147 transmits a signal from one end to the other end, and the second connection part 149 transmits the other end roll signal from one end.

The resonance adding section 151 adds at least one resonance band to the resonance frequency band of the antenna element 130. That is, the resonance adding section 151 determines the second resonance band in the resonance frequency band. The resonance adding section 151 is disposed between the feeding section 143 and the grounding section 145 in the resonance section 141. At this time, the resonance adding section 151 is connected to the resonance section 141. Here, the resonance adding unit 151 is connected to at least one of the feeding unit 143 and the grounding unit 145. As a result, a signal flows from the resonance unit 141 to the resonance addition unit 151.

The resonance adding portion 151 is connected to the grounding member 120. At this time, the resonance adding portion 151 is connected to the grounding member 120 through one end. Here, the resonance adding portion 151 is in contact with the grounding member 120 through one end. Further, the resonance adding section 151 extends from the grounding member 120. At this time, the resonance adding portion 151 extends from the grounding body 120 through the other end. In addition, the resonance adding portion 151 is connected to the resonance portion 141 via the other end. Here, the resonance adding portion 151 is connected between the first connecting portion 147 and the second connecting portion 149. Through this, the resonance adding portion 151 is grounded, and a signal is transmitted from the other end to the one end. In addition, the resonance adding portion 151 includes a conductive material. Here, the resonance adding unit 151 may include at least one of Ag, Pd, Pt, Cu, Au, and Ni.

Further, the resonance adding section 151 includes a reactance element 153. The reactance element 153 regulates the resonance frequency band in the antenna element 130. That is, the reactance element 153 controls the electrical characteristics of the antenna element 130. Here, the reactance element 153 regulates the second resonance band in the resonance frequency band of the antenna element 130. At this time, the reactance element 153 has a predetermined reactance. That is, the reactance element 153 adjusts the electrical characteristics of the antenna element 130 according to the reactance. Here, the reactance element 153 includes at least one of a capacitive element and an inductive element. For example, the capacitive element may be a capacitor. The inductive element may also be an inductor.

The adjustment unit 155 adjusts the connection position of the feed structure 140 and the radiator 170 in the antenna element 130. At this time, the adjusting portion 155 adjusts the connecting position of the resonator 141 and the radiator 170. The adjustment unit 155 may adjust the resonance frequency band of the antenna element 130. That is, the adjustment unit 155 can adjust the electrical characteristics of the antenna element 130. At this time, the adjusting unit 155 adjusts at least one of the first resonance band and the second resonance band in the resonance frequency band. The adjusting portion 155 is connected to the power feeder 143. At this time, the regulating portion 155 is disposed in the feed portion 143 according to the embodiment of the present invention. Here, the regulating unit 155 may be interposed in the power feeder 143. As a result, a signal flows from the power feeder 143 to the regulating unit 155.

The control unit 155 includes a plurality of connection units 157 and a switching unit 159. At this time, the connection portions 157 may be disposed at the output end of the power feeder 143, and the switching portion 159 may be disposed at the input end of the power feeder 143. That is, the connection portions 157 may be disposed close to the first connection portion 147, and the switching portion 159 may be disposed close to the grounding body 120. Here, the connection units 157 and the switching unit 159 may be connected in N: 1.

The connection portions (157) extend in parallel to the feed portion (143). At this time, the connection portions 157 are disposed apart from each other. Here, the connection portions 157 are arranged in parallel from the inside to the outside of the resonator portion 141. That is, the connection portions 157 are arranged in parallel to each other in a direction away from a position close to the resonance adding portion 151. And the connection portions 157 are connected to the switching portion 159 individually. Here, the connection portions 157 contact the switching portion 159 through respective one ends. Further, the connection portions 157 extend individually from the switching portion 159. [ Here, the connection portions 157 extend through the respective other ends. In addition, the connection portions 157 are individually connected to the grounding portion 145 at the output end of the power feeding portion 143. Specifically, the connection portions 157 are connected to the ground portion 145 through the first connection portion 147 and the second connection portion 149. Here, the connection portions 157 contact the first connection portion 147 through the other end portions. Thereby, any one of the connection portions 157 can supply a signal from one end to the other end. In addition, the connection portions 157 include a conductive material. Here, the connection portions 157 may include at least one of Ag, Pd, Pt, Cu, Au, and Ni.

The switching unit 159 electrically connects any one of the connection units 157 to the power supply unit 143. At this time, the switching unit 159 performs a switching operation under the control of the control unit (4 in Fig. 1). That is, the switching unit 159 performs a switching operation between the connection units 157 to provide any one of the connection units 157 to the connection position of the resonator unit 141 and the radiator 170. In other words, the switching portion 159 adjusts the connection position of the resonator 141 and the radiator 170 between the connection portions 157. [ To this end, the switching unit 159 is connected to the power feeder 143. And the switching unit 159 is connected to the connection units 157. [ Further, the switching unit 159 connects any one of the connection units 157 to the power feed unit 143 as selected by the control unit (40 of FIG. 1). The switching unit 159 may be configured to open and close the mechanical contact between each of the connection units 157 and the power feed unit 143 and may be configured to turn on or off the flow of the electrical signal.

That is, the feed structure 140 may be designed to have electrical characteristics corresponding to the resonance frequency band. For example, the feed structure 140 can be designed as shown in Fig. The resonance unit 1410 and the resonance addition unit 151 may be connected to the conductive line 163 connected to the feed point 161. The reactance element 153 may be the capacitor 165. In addition, The connection portions 157 may be connected to the plurality of branch lines 167 and the switching portion 159 may be connected to the switch 169. The branch lines 167 may be connected to the conductive line 163 And the switch 169 may be disposed between the feed point 161 and the branch line 167. In addition, the switch 169 may perform a switching operation between the branch lines 167. [ Thus, the switch 169 can connect any one of the branch lines 167 to the feed point 161.

The radiator 170 is provided for practical operation at the antenna element 130. [ At this time, the radiator 170 operates in the resonance frequency band. That is, a signal is supplied from the power supply structure 140, the radiator 170 operates. And the radiator 170, together with the feed structure 140, operate.

The radiator 170 is connected to the power supply structure 140. At this time, the radiator 150 is electrically connected to the resonator 141. And the radiator 170 includes a plurality of contact portions 171. At this time, the contact portions 171 correspond to the connection portions 157 of the adjustment portion 155 individually. The contacts 171 also contact the contacts 157 individually. In addition, any one of the contact portions 171 is electrically connected to the power supply portion 143. [ Concretely, any one of the contact portions 171 is electrically connected to the power feed portion 143 as one of the contact portions 157 is connected to the power feed portion 143 by the switching portion 159. Here, each of the contact portions 171 may be formed as a pin type or a C-clip. In addition, the radiator 170 is made of a conductive material. Here, the radiator 170 may include at least one of Ag, Pd, Pt, Cu, Au, and Ni.

The mounting member 180 is provided for supporting the radiator 170 in the antenna device 100. [ That is, as the radiator 170 is mounted on the mounting member 180, the mounting member 180 supports the radiator 170. Although not shown, when the antenna device 100 is mounted on the communication terminal (10 in Fig. 1), the mounting member 180 is connected to the inside of the outer case (not shown) Can be mounted on the surface. Here, the driving substrate 110 may be disposed in an inner space formed by the outer case of the communication terminal (10 of FIG. 1).

These mounting members 180 are disposed corresponding to the driving substrate 110. [ Here, the mounting member 180 is disposed corresponding to the antenna region 113 of the driving substrate 110. [ The mounting member 180 is spaced from the driving substrate 110 or the power supply structure 140. The mounting member 180 also includes a lower surface 181, a top surface 183 corresponding to the lower surface 181 and a side surface 185 connecting the lower surface 181 and the upper surface 183. Here, the mounting member 180 can be mounted to the outer case of the communication terminal (10 in Fig. 1) through the upper surface 183.

At this time, the radiator 170 can be mounted on the lower surface 181 of the mounting member 180. The radiator 170 may be mounted on the upper surface 183 of the mounting member 180, although not shown. Here, the radiator 170 may be interposed between the outer case of the communication terminal (10 of FIG. 1) and the mounting member 180. And the radiator 170 may extend to the lower surface 181 along the side surface 185 of the mounting member 180. [ On the other hand, the radiator 170 may extend through the mounting member 180 to the lower surface 181. The contact portion 171 of the radiator 170 can be disposed in a space between the resonator portion 141 of the drive substrate 110 and the mounting member 180. [

Thereby, the antenna device 100 operates in the resonance frequency band. For example, the antenna device 100 may have the operating characteristics as shown in Fig. At this time, the feed structure 140 and the radiator 170 operate together in the resonance frequency band. Here, when a signal is applied from the driving substrate 110, a signal is transmitted from the power supply structure 140. Then, a signal is supplied from the feed structure 140 to the radiator 170. Also in the feed structure 140, two resonant loops are formed, a first resonant loop and a second resonant loop. In addition, the resonance frequency band is determined according to the resonance loops of the feed structure 140.

At this time, the first resonance loop is formed by the resonance part 141. That is, the first resonant loop is formed by the feeding part 143, the ground part 145, the first connecting part 147 and the second connecting part 149. The first resonant loop determines the first resonant band in the resonant frequency band of the antenna element 130. Here, the first resonance band is determined according to the size of the first resonance loop. On the other hand, the second resonant loop is formed by the ground portion 145, the second connection portion 149, and the resonant addition portion 151. And the second resonance loop determines the second resonance band in the resonance frequency band of the antenna element 130. [ Here, the second resonance band is determined in accordance with the size of the second resonance loop and the reactance of the reactance element 153.

The size of the first resonant loop and the size of the second resonant loop are adjusted as the connecting position of the resonator 141 and the radiator 170 is adjusted by the adjusting unit 155. That is, the size of the first resonant loop and the size of the second resonant loop are adjusted in accordance with the positions of the connection portions 157 in the regulating portion 155. At this time, the size of the first resonance loop and the size of the second resonance loop can be reduced as the connection portions 157 are located inside the resonance portion 141. In other words, the size of the first resonance loop and the size of the second resonance loop can be enlarged as the connection portions 157 are located outside the resonance portion 141.

Also, as the size of the first resonant loop and the size of the second resonant loop are adjusted, the first resonant band and the second resonant band are adjusted while the operating performance of the antenna device 100 is maintained. At this time, as the size of the first resonance loop and the size of the second resonance loop are reduced, the first resonance band and the second resonance band can be adjusted to a higher frequency region. In other words, as the size of the first resonance loop and the size of the second resonance loop are enlarged, the first resonance band and the second resonance band can be adjusted to a lower frequency region.

In addition, the second resonance band can be adjusted in accordance with the reactance of the reactance element 153. At this time, as the reactance of the reactance element 153 decreases, the second resonance band can be adjusted to a higher frequency region. In other words, as the reactance of the reactance element 153 is increased, the second resonance band can be adjusted to a lower frequency region.

In the present embodiment, the connection portions 157 are disposed at the output end of the power feeder 143, and the switching portion 159 is disposed at the input end of the power feeder 143. However, the present invention is not limited thereto. That is, the connection units 157 and the switching unit 159 in the control unit 155 may be arranged as shown in FIG. Specifically, the connection portions 157 may be disposed at the input end of the power feeder 143, and the switching portion 159 may be disposed at the output end of the power feeder 143. In other words, the connection portions 157 may be disposed close to the grounding member 120, and the switching portion 159 may be disposed close to the first connection portion 147. Here, the connection units 157 and the switching unit 159 may be connected in N: 1.

At this time, the connection portions 157 are individually connected to the power feeding portion 143. Here, the connection portions 157 are in contact with the feed portion 143 via their one ends. And the connection portions 157 extend individually from the power feeder 143. [ Here, the connection portions 157 extend through the respective other ends. Further, the connection portions 157 are individually connected to the switching portion 159. Here, the connection portions 157 are connected to the switching portion 159 through the respective other ends. The switching unit 159 is connected to the connection units 157. [ In addition, the switching unit 159 is individually connected to the grounding unit 145 at the output terminal of the power feeding unit 143. Specifically, the switching unit 159 is connected to the grounding unit 145 through the first connection unit 147 and the second connection unit 149. Thereby, any one of the connection portions 157 can supply a signal from one end to the other end.

7 and 8 are views showing an antenna device according to a second embodiment of the present invention. 7 is a perspective view of the antenna device according to the second embodiment of the present invention, and FIG. 8 is a plan view showing a part of the configuration of the antenna device in FIG. And FIG. 9 is a plan view showing a modified example of the antenna device according to the second embodiment of the present invention.

7 and 8, the antenna device 200 of the present embodiment includes a driving substrate 210, a grounding member 220, an antenna element 230, and a mounting member 280. The antenna element 230 includes a feed structure 240 and a radiator 270. The power supply structure 240 also includes a resonator 241, a resonator 251, and an adjuster 255. At this time, the resonance part 241 includes the feed part 243, the ground part 245, the first connection part 247 and the second connection part 249. In addition, the resonance adding section 251 includes the reactance element 253. Here, each configuration in the present 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 adjustment portion 255 is disposed in the first connection portion 247 according to the embodiment of the present invention. Here, the adjustment unit 255 may be interposed in the first connection unit 247. That is, the regulating part 255 is connected to the feed part 243 at the first connection part 247. As a result, a signal flows from the power feeder 243 to the regulator 255.

The control unit 255 includes a plurality of connection units 257 and a switching unit 259. At this time, the connection portions 257 may be disposed at the output end of the first connection portion 247, and the switching portion 259 may be disposed at the input end of the first connection portion 247. The connection portions 257 may be disposed close to the second connection portion 249 and the resonator attachment portion 251 and the switching portion 259 may be disposed close to the feed portion 243. [ Here, the connection units 257 and the switching unit 259 may be connected in N: 1.

The connection portions 257 extend in parallel to the first connection portion 247. At this time, the connection portions 257 are spaced apart from each other. Here, the connection portions 257 are arranged in parallel to each other from the inside to the outside of the resonator portion 241. That is, the connection portions 257 are arranged side by side in a direction away from a position close to the grounding member 220. The connection units 257 are connected to the switching unit 259 individually. Here, the connection portions 257 are in contact with the switching portion 259 through respective one ends thereof. Further, the connection portions 257 extend individually from the switching portion 259. Here, the connection portions 257 extend through the respective other ends. In addition, the connection portions 257 are individually connected to the ground portion 245 at the output end of the first connection portion 247. Specifically, the connection portions 257 are connected to the ground portion 245 through the second connection portion 249. [ Here, the connection portions 257 are in contact with the second connection portions 249 through the respective other ends. Thereby, any one of the connection portions 257 can supply a signal from one end to the other end. In addition, the connection portions 257 include a conductive material. Here, the connection portions 257 may include at least one of Ag, Pd, Pt, Cu, Au, and Ni.

The switching unit 259 electrically connects any one of the connection units 257 to the power feed unit 243. At this time, the switching unit 259 performs a switching operation under the control of the control unit (4 in Fig. 1). That is, the switching unit 259 performs a switching operation between the connection units 257 to provide any one of the connection units 257 to the connection position of the resonator unit 241 and the radiator 270. In other words, the switching section 259 adjusts the connection position of the resonator section 241 and the radiator 270 between the connection sections 257. To this end, the switching unit 259 is connected to the feeding part 243 at the input end of the first connecting part 247. The switching unit 259 is connected to the connection units 257. Further, the switching unit 259 connects any one of the connection units 257 to the feed unit 243 as selected by the control unit (40 in FIG. 1). The switching unit 259 may be configured to open and close mechanical contact between each of the connection units 257 and the power feed unit 243 and may be configured to turn on or off the flow of electrical signals.

In the antenna device 200 of the present embodiment, the radiator 270 is connected to the power supply structure 240. At this time, the radiator 250 is electrically connected to the resonator 241. The radiator 270 also includes a plurality of contact portions 271. At this time, the contact portions 271 correspond to the connection portions 257 of the adjustment portion 255 individually. In addition, the contact portions 271 individually contact the connection portions 257. Further, any one of the contact portions 271 is electrically connected to the power feeding portion 243. Concretely, any one of the contact portions 271 is electrically connected to the feed portion 243, as one of the connection portions 257 is connected to the feed portion 243 by the switching portion 259. Here, each of the contact portions 271 may be formed as a pin type or a C-clip. The radiator 270 is made of a conductive material. Here, the radiator 270 may include at least one of Ag, Pd, Pt, Cu, Au, and Ni.

Thus, the antenna device 200 operates in the resonance frequency band. For example, the antenna device 200 may have operational characteristics similar to those described above. At this time, the feed structure 240 and the radiator 270 operate together in the resonant frequency band. Here, when a signal is applied from the driving substrate 210, a signal is transmitted from the power supply structure 240. Then, a signal is supplied from the feed structure 240 to the radiator 270. Also in the feed structure 240, two resonant loops are formed, a first resonant loop and a second resonant loop. In addition, the resonant frequency bands are determined in accordance with the resonant loops of the feed structure 240.

At this time, the first resonance loop is formed by the resonance portion 241. That is, the first resonant loop is formed by the feeding part 243, the ground part 245, the first connecting part 247 and the second connecting part 249. The first resonant loop determines the first resonant band in the resonant frequency band of the antenna element 130. Here, the first resonance band is determined according to the size of the first resonance loop. On the other hand, the second resonance loop is formed by the ground portion 245, the second connection portion 249, and the resonance adding portion 251. And the second resonant loop determines the second resonant band in the resonant frequency band of the antenna element 230. [ Here, the second resonance band is determined in accordance with the size of the second resonance loop and the reactance of the reactance element 253.

As the connecting position of the resonator 241 and the radiator 270 is adjusted by the adjusting unit 255, the size of the first resonant loop and the size of the second resonant loop are adjusted. In other words, the size of the first resonant loop and the size of the second resonant loop are adjusted in accordance with the positions of the connection portions 257 in the regulating portion 255. At this time, the size of the first resonance loop and the size of the second resonance loop can be reduced as the connection portions 257 are located inside the resonance portion 241. In other words, the size of the first resonance loop and the size of the second resonance loop can be enlarged as the connection portions 257 are located outside the resonance portion 241.

Also, as the size of the first resonant loop and the size of the second resonant loop are adjusted, the first resonant band and the second resonant band are adjusted while the operating performance of the antenna device 100 is maintained. At this time, as the size of the first resonance loop and the size of the second resonance loop are reduced, the first resonance band and the second resonance band can be adjusted to a higher frequency region. In other words, as the size of the first resonance loop and the size of the second resonance loop are enlarged, the first resonance band and the second resonance band can be adjusted to a lower frequency region.

In addition, the second resonance band can be adjusted in accordance with the reactance of the reactance element 253. At this time, as the reactance of the reactance element 253 decreases, the second resonance band can be adjusted to a higher frequency region. In other words, as the reactance of the reactance element 253 is increased, the second resonance band can be adjusted to a lower frequency region.

Although the connection portions 257 are disposed at the output end of the first connection portion 247 and the switching portion 259 is disposed at the input end of the first connection portion 247 in the present embodiment, . That is, the connection units 257 and the switching unit 259 in the control unit 255 may be arranged as shown in FIG. Specifically, the connection portions 257 are disposed close to the power feed portion 243, and the switching portion 259 can be disposed close to the second connection portion 249 and the resonator attachment portion 251. [ Here, the connection units 257 and the switching unit 259 may be connected in N: 1.

At this time, the connection portions 257 are individually connected to the power feeding portion 243. Here, the connection portions 257 are in contact with the power feeding portion 243 via their one ends. And the connection portions 257 extend individually from the feeding portion 243. Here, the connection portions 257 extend through the respective other ends. Further, the connection portions 257 are individually connected to the switching portion 259. Here, the connection portions 257 are connected to the switching portion 259 through the respective other ends. The switching unit 259 is connected to the connection units 257. In addition, the switching unit 259 is individually connected to the ground unit 245 at the output terminal of the first connection unit 247. Specifically, the switching unit 259 is connected to the ground unit 245 through the second connection unit 249. [ Thereby, any one of the connection portions 257 can supply a signal from one end to the other end.

According to the present invention, in the antenna apparatuses 100 and 200, the adjustment units 155 and 255 can easily adjust the resonance frequency band. At this time, the resonance frequency band can be adjusted while the operation performance of the antenna devices 100 and 200 is maintained according to the switching operation of the adjusting units 155 and 255. Accordingly, the antenna apparatuses 100 and 200 can selectively connect to a plurality of communication networks. That is, the antenna apparatuses 100 and 200 can adjust the resonance frequency band to connect to a desired communication network. In addition, even if the physical length of the antenna elements 130 and 230 does not increase in the antenna devices 100 and 200, the resonance frequency band can be adjusted. Therefore, the resonance frequency band can be adjusted without enlarging the size of the antenna apparatuses 100 and 200.

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: antenna device 110, 210: driving substrate
120, 220: grounding member 130, 230: antenna element
140, 240: power supply structure 141, 241:
143, 243: power feeder 145, 245:
147, 247: first connection 149, 249: second connection
151, 251: Resonance adding section 153, 253: Reactance element
155, 255: regulating unit 157, 257:
159, 259: switching part 170, 270: radiator
171, 271:

Claims (18)

The radiator,
And a feed structure for driving the radiator,
The power supply structure includes:
A resonance part including a feed part for supplying a signal to the radiator and a ground part connected to the feed part,
A resonance adding portion disposed between the feeding portion and the grounding portion,
And an adjusting unit connected to the feeding unit and adjusting a position where the radiator and the resonator unit are connected,
Wherein the adjusting portion includes a plurality of connecting portions arranged to be spaced from each other, and electrically connecting any one of the connecting portions to the feeding portion,
Wherein the radiator comprises a plurality of contacts each of which is in contact with the connections. delete The apparatus according to claim 1,
Further comprising a switching unit for electrically connecting any one of the connection units to the power feed unit. The apparatus of claim 1,
Wherein the first and second antenna elements are arranged in parallel to each other from the inner side to the outer side of the resonance part. delete The radiator,
And a feed structure for driving the radiator,
The power supply structure includes:
A resonance part including a feed part for supplying a signal to the radiator and a ground part connected to the feed part,
A resonance adding portion disposed between the feeding portion and the grounding portion,
And an adjusting unit connected to the feeding unit and adjusting a position where the radiator and the resonator unit are connected,
Wherein the adjusting portion includes a plurality of connecting portions arranged to be spaced apart from each other, and electrically connecting any one of the connecting portions to the feeding portion,
Wherein the connection portions are individually connected to the grounding portion. The method of claim 3,
Further comprising a controller for selecting any one of the connection units and controlling the switching unit to connect the selected connection unit to the power supply unit. The radiator,
And a feed structure for driving the radiator,
The power supply structure includes:
A resonance part including a feed part for supplying a signal to the radiator and a ground part connected to the feed part,
A resonance adding portion disposed between the feeding portion and the grounding portion,
And an adjusting unit connected to the feeding unit and adjusting a position where the radiator and the resonator unit are connected,
Wherein the adjusting unit adjusts a size of a resonance loop formed in the power supply structure. 9. The resonator according to claim 8,
A first resonant loop formed by connecting the feed part and the ground part,
And a second resonant loop formed by connecting the ground portion and the resonant addition portion. 10. The apparatus according to claim 9,
And adjusts the size of the first resonant loop. A resonance part including a feed part supplying a signal and a ground part connected to the feed part,
A resonance adding portion disposed between the feeding portion and the grounding portion,
And an adjusting unit connected to the power feeding unit to adjust a position at which the signal is output from the resonating unit,
Wherein the adjusting portion includes a plurality of connecting portions arranged to be spaced from each other, and electrically connecting any one of the connecting portions to the feeding portion,
Wherein the control unit includes a switching unit for electrically connecting any one of the connection units to the power supply unit,
And the connection portions are individually connected to the grounding portion. delete 12. The apparatus according to claim 11,
Further comprising a switching unit for electrically connecting any one of the connection units to the power supply unit. 14. The apparatus of claim 13,
Wherein the connection portions and the switching portion are connected by N: 1. 12. The apparatus of claim 11,
And the resonator are arranged in parallel to each other from the inner side to the outer side of the resonance part. delete 14. The method of claim 13,
Further comprising a control unit for selecting any one of the connection units and controlling the switching unit to connect the selected connection unit to the power supply unit. A resonance part including a feed part supplying a signal and a ground part connected to the feed part,
A resonance adding portion disposed between the feeding portion and the grounding portion,
And an adjusting unit connected to the feeding unit to adjust a position at which the signal is output from the resonating unit,
Wherein the adjustment unit adjusts the size of at least one of the resonance loops formed in the feed structure.

Images