KR20100101312A - Multi-band antenna - Google Patents

Abstract

PURPOSE: A multi-band antenna is provided to implement different frequency bands by selectively mixing a plurality of radiator patterns. CONSTITUTION: A multi-band antenna comprises a main radiator pattern(110), a low frequency radiator stub(230), and a high frequency radiation stub(220). A first radiator pattern with a low frequency band property is formed in one side of the main radiator pattern. A second radiation pattern with a high frequency band property is formed in the other side of the main radiator pattern. The low frequency radiator stub is selectively connected to the predetermined region of the first radiator pattern in order to diversify the frequency band property of the first radiator pattern. The high frequency radiation stub is selectively connected to the predetermined region of the second radiation pattern in order to diversify the frequency band property of the second radiation pattern.

Description

Multi-band Antenna

The present invention relates to a multiband antenna, and more particularly, to an antenna that satisfies various frequency band characteristics such as G850, EGSM, DCS and PCS by combining a plurality of radiator patterns in combination.

At present, due to the rapid development of digital communication technology, various kinds of communication services are provided worldwide. High-speed information and communication infrastructure using wireless has been established at home and abroad. For this reason, the frequency bandwidth of the communication system is increasing due to the use of different standards corresponding to different frequency bands and the increase in the bit rate. There is an active research on antennas satisfying various frequency bands.

In accordance with the development of wireless communication devices and portable convenience, built-in antennas in which antennas are embedded in communication devices have been developed, but mobile communication terminals, etc. in which the built-in antennas are provided, have low bandwidth because of wideband characteristics. For this reason, there is a problem in that it is not suitable for wideband and multibandization according to the multifunctional communication service.

The general MPA type multiband antenna supports dual band, and a dual band antenna to cover the frequency bands of the G850 and PCS or a dual band antenna to cover the frequency bands of EGSM and DCS has been developed depending on the use place and purpose. .

However, to meet all four bands of the G850, EGSM, DCS and PCS, the antenna's implementation is not easy due to the large volume and complex radiation pattern of the antenna. In addition, to implement an antenna that satisfies all four bands, which are adjacent frequencies, a wideband resonant band is required, but this is difficult to implement physically and technically.

The present invention provides a multi-band antenna having a plurality of frequency band characteristics, preferably satisfy all four bands of G850, EGSM, DCS and PCS, in addition to a variety of WCDMA band, GPS band, Bluetooth band, etc. It is an object to provide an antenna having a band characteristic.

Furthermore, the present invention aims to miniaturize the antenna volume and provide an antenna capable of covering various frequency bands with a simple radiation pattern.

In order to achieve the above technical problem, the present invention, in the multi-band internal antenna, a plurality of radiator patterns are selectively connected, each having a different frequency band characteristics according to the combination of radiator patterns connected to each other Antenna.

Preferably, one side is formed of a first radiator pattern having low frequency band characteristics, and the other side is formed of a second radiator pattern having high frequency band characteristics; A low frequency radiator stub selectively connected to a predetermined portion of the first radiator pattern to vary a frequency band characteristic of the first radiator pattern; And a high frequency radiator stub selectively connected to a predetermined portion of the second radiator pattern to change a frequency band characteristic of the second radiator pattern.

More preferably, the first switch for selectively connecting the first radiator pattern and the low frequency radiator stub; And a second switch for selectively connecting the second radiator pattern and the high frequency radiator stub.

Furthermore, the radiator pattern and the base block further comprises a stub, the first radiator fin is formed to protrude to the outside of the side of the base block, respectively, and connected to the first radiator pattern; A high frequency radiator pin connected to the high frequency radiator stub; A second radiator fin connected to the second radiator pattern; And a low frequency radiator pin connected to the low frequency radiator stub, wherein the first radiator pin and the low frequency radiator pin are connected to the first switch, and the second radiator pin and the high frequency radiator pin are connected to the second switch. Can be connected.

In addition, a feed line and a ground line respectively connected to the stop portion of the main radiator pattern are formed on the base block, and at the end of the feed line and the end of the ground line, respectively, protrude out of the side of the base block. Pins and ground line pins may be formed.

Preferably, the first radiator fin, the second radiator fin, the high frequency radiator fin, the low frequency radiator fin, the feed line pin, and the ground line pin may be formed by surface mount (SMT) on the PCB substrate.

In addition, the first radiator fin, the second radiator fin, the high frequency radiator fin, the low frequency radiator fin, the feed line pin and the ground line pin may be mounted on the PCB substrate in the form of a c-clip or a tension. .

Here, the base block may be an injection molding using a thermosetting synthetic resin.

Preferably, the first switch and the second switch can be operated by a power input from the outside.

Furthermore, the first switch and the second switch in the off state (off) has the frequency band characteristics of the EGSM and PCS, the first switch is on (on) and the second switch is off (off) G850 And a frequency band characteristic of PCS, wherein the first switch is off and the second switch is on, and has a frequency band characteristic of EGSM and DCS. It may have the frequency band characteristics of the G850 and DCS in the on (on) state.

According to the present invention, it is possible to provide a multi-band antenna having a variety of characteristics of a plurality of frequency bands, in detail not only satisfy the four frequency bands of G850, EGSM, DCS, PCS, but also radiator pattern And an antenna having various band characteristics such as a WCDMA band, a GPS band, and a Bluetooth band according to a combination of a plurality of radiator patterns.

Furthermore, by satisfying a plurality of frequency bands with one antenna, the efficiency of operation of a wireless communication device is increased, and a simple radiator pattern is provided, thereby providing an antenna that is easy to manufacture and low in production cost.

In addition, by forming the radiator pattern by utilizing each surface on the base block to the maximum, the size of the antenna can be miniaturized, and the antenna feeding line can be surface mounted on the PCB substrate to minimize the frequency interference caused by external devices.

In order to explain the present invention, the operational advantages of the present invention and the objects achieved by the practice of the present invention, the following describes exemplary embodiments of the present invention and looks at it with reference.

The present invention is a multi-band antenna having a different frequency band characteristics according to a combination of radiator patterns connected to each other of the plurality of radiator patterns by selectively connecting a plurality of radiator patterns, one antenna selectively frequency band as needed This antenna can be changed.

1 shows an exploded view of an embodiment of a multiband antenna according to the present invention.

Referring to the present invention through the embodiment of Figure 1, one side of the main radiator pattern 110 is formed of a first radiator pattern 130 having a low frequency band characteristics, the other side of the second radiator pattern 120 having a high frequency band characteristics Is formed.

Although the first radiator pattern 130 exhibits low frequency band characteristics, substantially the first resonance in the low frequency band of the main radiator pattern 110 is performed by the first radiator pattern 130 and the second radiator pattern 120. It may be generated over the entire length, and the second resonance in the high frequency band may be generated by the second radiator pattern 120.

That is, in order to configure the antenna for each frequency band to have a length for receiving the corresponding frequency, the length of the antenna satisfying the low frequency band is relatively high because the length of the antenna is inversely proportional to the frequency of the signal and is proportional to the wavelength of the signal. It is formed longer than the length of the antenna to meet.

In the present invention, an additional high frequency radiator stub 220 and a low frequency radiator stub 230 are formed to selectively adjust the length of such an antenna to the main radiator pattern 110 according to a frequency band required by a user. Optionally, the high frequency radiator stub 220 or the low frequency radiator stub 230 is connected.

In order to adjust the selective antenna length, a second switch 250 is installed between the high frequency radiator stub 220 and the second radiator pattern 120 to selectively select the high frequency radiator stub 220 and the second radiator pattern 120. The first switch 230 is installed between the low frequency radiator stub 230 and the first radiator pattern 130 to selectively connect the low frequency radiator stub 230 and the first radiator pattern 130.

A power supply line 260 for feeding power to the main radiator pattern 110 is connected to a stop portion of the main radiator pattern 110, and a ground line 270 for grounding is connected.

The multi-band antenna 100 according to the present invention can form a respective radiator pattern on each surface on the hexahedral base block to further reduce the size, in the embodiment of FIG. It is a development view.

Figure 2 shows a front view from above of the antenna 100 according to the present invention with each side folded in the above embodiment.

As shown in FIG. 2, when the antenna according to the present invention is viewed from above, respective radiator patterns are formed on the base block 200, extend to the feed line 260, and are led out of the base block 200 to feed the power. The line pin 265 is formed and extends to the ground line 270 to protrude out of the base block 200 to form the ground line pin 275.

In addition, in order to connect the second radiator pattern 120 and the high frequency radiator stub 220 to the second switch 250, each of the second radiator fin 255b and the high frequency radiator fin 255a are protruded out of the base block 200. ) Is formed and protrudes out of the base block 200 to connect the first radiator pattern 130 and the low frequency radiator stub 230 to the first switch 240 and each of the first radiator fins 245b. The low frequency radiator fin 245a is formed.

Figure 3 shows a perspective view of an embodiment of a multi-band antenna 100 according to the present invention, each radiator pattern is formed on the hexahedral base block 200, as shown in Figure 3 and the bottom surface of the base block 200 and Protruding outward in parallel, the feed line pin 265, the ground line pin 275, the second radiator fin 255b, the first radiator fin 245b, the high frequency radiator fin 255a and the low frequency radiator fin 245a Formed.

Although not shown on FIG. 3, the feed line pin 265, the ground line pin 275, the second radiator fin 255b, the first radiator fin 245b, the high frequency radiator fin 255a, and the low frequency radiator fin ( 245a) may be formed by surface mount (SMT) on the PCB substrate for convenience when the multi-band antenna 100 according to the present invention is mounted on the substrate and to minimize the frequency interference of peripheral devices. Depending on the communication device to be mounted, each pin of the antenna may be mounted on the communication device in a c-clip type or a tension type.

Here, the base block 200 may be an injection molding using a thermosetting synthetic resin to withstand the high temperature at the time of surface mount (SMT) on the PCB substrate, but is not limited to this, in the case of mounting the antenna in the sea clip type or tension type is common Various forms such as injection molded products such as plastic may be used.

The following describes the operation according to the embodiment of the multi-band antenna according to the present invention.

Table 1 below shows the change of the antenna frequency band characteristics according to each switch operation of the multi-band antenna according to the present invention.

First switch OFF ON Second switch OFF EGSM & PCS G850 & PCS ON EGSM & DCS G850 & DCS

TABLE 1

When both the first switch 240 and the second switch 250 are in an off state, the high frequency radiator stub 220 and the low frequency radiator stub 230 are not connected to the main radiator pattern 110. In this case, it has the dual band characteristics of EGSM and PCS.

When the first switch 240 is off and the second switch 250 is on, the high frequency radiator stub 220 is applied to the second radiator pattern 120 of the main radiator pattern 110. In the connected state, in this case, it has dual band characteristics of EGSM and DCS.

When the first switch 240 is on and the second switch 250 is off, the low frequency radiator stub 230 is connected to the first radiator pattern 130 of the main radiator pattern 110. In this case, it has dual band characteristics of G850 and PCS.

Finally, when both the first switch 240 and the second switch 250 are turned on, the high frequency radiator stub 220 is applied to each of the first radiator pattern 130 and the second radiator pattern 120 of the main radiator pattern. ) And the low frequency radiator stub 230 is connected, in which case it has dual band characteristics of G850 and DCS.

As described above, in the multi-band antenna according to the present invention, the frequency band characteristics are selectively changed by the operation of the switch, so that the user can select a desired frequency band. In this case, the first switch 240 and the second switch 250 are provided from the outside. Driven according to the input voltage, both switches can be driven at an input voltage of 3V or 5V, preferably different driving voltages, for example, one of the two switches to drive the input voltage of 5V and the other Can be driven according to the input voltage of 3V.

4 is a graph showing selective frequency band characteristics of a multi-band antenna according to the present invention.

4A illustrates a case in which the low frequency band has dual band characteristics of EGSM of 880 to 960 MHz and DCS of high frequency band of 1710 to 1880 MHz. In an embodiment of the multi-band antenna according to the present invention, the first switch 240 is turned off. (off) and the frequency band graph when the second switch 250 is on.

4B illustrates a case in which the low frequency band has a dual band characteristic of a G850 having a low frequency band of 824 to 894 MHz and a PCS having a high frequency band of 1850 to 1990 MHz. (on) and the frequency band graph when the second switch 250 is off.

As described above, in the present invention, the frequency band is selectively changed. As a result, as shown in c) of FIG. 4, in the case of the independent frequency band, a bandwidth of 824 to 960 MHz may satisfy approximately 140 MHz. In addition, in the case of a high frequency band, a band width of 1710 to 1990 MHz may satisfy approximately 280 MHz.

Furthermore, as shown in FIG. 4, in the case of the multi-band antenna according to the present invention, the VSWR value exhibits stable frequency characteristics of about 3 degrees.

In the above embodiment, a four-band antenna that satisfies the frequency bands of EGSM, G850, DCS and PCS has been described, but is not limited thereto. Various frequency bands, such as bands and Bluetooth bands, can be selectively met.

The foregoing description is merely illustrative of the technical idea of the present invention, and various changes and modifications may be made by those skilled in the art without departing from the essential characteristics of the present invention. Therefore, the embodiments described in the present invention are not intended to limit the technical idea of the present invention but to describe the present invention, and the technical idea of the present invention is not limited to these embodiments. The protection scope of the present invention should be interpreted by the following claims, and all technical ideas within the equivalent scope should be interpreted as being included in the scope of the present invention.

1 shows an exploded view of an embodiment of a multi-band antenna according to the present invention,

2 shows a front view from above of an embodiment of a multi-band antenna according to the invention of FIG. 1,

3 shows a perspective view of an embodiment of a multi-band antenna according to the invention of FIG. 1,

Figure 4 shows a frequency band graph for the selective frequency band characteristics of the multi-band antenna according to the present invention.

<Description of Major Symbols in Drawing>

100: multiband antenna,

110: main emitter pattern, 120: second emitter pattern,

130: first radiator pattern,

200: base block,

220: high frequency radiator stub, 230: low frequency radiator stub,

240: first switch, 250: second switch,

260: power supply line, 370: ground line.

Claims (10)

In the multiband internal antenna, A plurality of radiator patterns are selectively connected, and each multiband internal antenna having different frequency band characteristics according to the combination of the radiator patterns connected to each other. The method of claim 1, A main radiator pattern having one side formed of a first radiator pattern having a low frequency band characteristic, and the other side formed of a second radiator pattern having a high frequency band characteristic; A low frequency radiator stub selectively connected to a predetermined portion of the first radiator pattern to vary a frequency band characteristic of the first radiator pattern; And And a high frequency radiator stub which is selectively connected to a predetermined portion of the second radiator pattern to change a frequency band characteristic of the second radiator pattern. The method of claim 2, A first switch for selectively connecting the first radiator pattern and the low frequency radiator stub; And And a second switch for selectively connecting the second radiator pattern and the high frequency radiator stub. The method of claim 3, wherein And a base block on which the radiator patterns and the stubs are formed. Are formed to protrude to the outside of the side of the base block, respectively, A first radiator fin connected to the first radiator pattern; A high frequency radiator pin connected to the high frequency radiator stub; A second radiator fin connected to the second radiator pattern; And And a low frequency radiator pin connected to said low frequency radiator stub. The first radiator pin and the low frequency radiator pin are connected to the first switch, And the second radiator pin and the high frequency radiator pin are connected to the second switch. The method of claim 3, wherein Feed lines and ground lines respectively connected to the stop portions of the main radiator pattern are formed on the base block, And a feed line pin and a ground line pin formed at the end of the feed line and the end of the ground line, respectively, to protrude outward from the side surfaces of the base block. The method according to claim 4 or 5, And the first radiator fin, the second radiator fin, the high frequency radiator fin, the low frequency radiator fin, the feed line pin, and the ground line pin are formed by surface mount on a PCB substrate. The method according to claim 4 or 5, The first radiator fin, the second radiator fin, the high frequency radiator fin, the low frequency radiator fin, the feed line pin and the ground line pin are mounted on the PCB substrate in the form of a c-clip or a tension. Multiband internal antenna. The method of claim 6, The base block is a multi-band internal antenna, characterized in that the injection molding using a thermosetting synthetic resin. The method according to any one of claims 3 to 5, The first switch and the second switch is a multi-band internal antenna, characterized in that the operation by the power input from the outside. The method according to any one of claims 3 to 5, In the state that the first switch and the second switch (off) has the frequency band characteristics of EGSM and PCS, Has a frequency band characteristic of G850 and PCS when the first switch is on and the second switch is off; Has a frequency band characteristic of EGSM and DCS when the first switch is off and the second switch is on And a frequency band characteristic of G850 and DCS when the first switch and the second switch are turned on.

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