KR20080058736A - Mobile communication terminal and antenna thereof - Google Patents

Abstract

A mobile terminal and its antenna are provided to transmit/receive a multi-band signal easily by having a wide bandwidth and a high antenna gain by performing impedance matching on a short-circuit signal of a radiation unit. A feeder(20) feeds a signal to a radiation unit(10). The first matching unit(30) performs impedance matching between the feeder and a signal transmission/reception end of a main circuit board(2) of a main body that transmits/receives a signal to/from the feeder. The second matching unit(40) is formed as a matching element between the radiation unit and ground surface(2a) of the main circuit board of the main body. The matching element is at least one of a coil and a capacitor. The second matching unit is formed as the coil and the capacitor is connected in series or in parallel. The second matching unit operates as a short-circuit unit of a PIFA(Planar Inverted F-type Antenna).

Description

Mobile communication terminal and antenna thereof

1 is a perspective view illustrating an antenna configuration of a mobile communication terminal according to the present invention;

2 is a reference to the description of the embodiment for the second matching portion according to the present invention;

3 is a chart showing the standing wave ratio characteristics of the antenna according to the present invention; and

4 is a graph showing the standing wave ratio characteristics of the antenna according to the present invention.

Explanation of symbols on the main parts of the drawings

2: main circuit board 10: radiating part

 20: power supply unit 30: first matching unit

40: second matching part

The present invention relates to a mobile communication terminal and an antenna thereof, and more particularly, to a mobile communication terminal and an antenna thereof having a matching element at a feed end of the antenna to enable impedance matching of an output signal.

The antenna of the mobile communication terminal transmits a signal output from a printed circuit board (PCB) of the main body to a radiator through a feeder, and the radiator transmits and receives a signal of a predetermined frequency band. At this time, a matching circuit is provided between the main circuit board and the power supply unit, so that the impedance is matched with the signal output from the main circuit board, and then the power is supplied to the radiation unit through the power supply unit.

However, in the case of the antenna configured as described above, the impedance matching becomes weak when the impedance matching of the output signal is made through the matching circuit, and if more matching elements are used to increase the antenna gain, the matching rate is lowered. As a result, the adverse effect appears. Therefore, in the implementation of the matching circuit, the impedance matching range for the output signal is limited and thus stronger impedance matching is not possible.

Accordingly, an object of the present invention is to provide a mobile communication terminal and an antenna thereof having a matching element at the end of a feeder so that the antenna gain is increased by matching an output signal.

The antenna of the mobile communication terminal according to the present invention for solving the above problems, a radiator, a feeder for feeding a signal to the radiating portion, the signal transmission and reception of the main circuit board main body for transmitting and receiving signals to the feeder and the feeder And a second matching portion formed of a matching element connected between the radiating portion and the ground plane of the main circuit board of the main circuit board, the first matching portion performing impedance matching between stages.

In addition, the mobile communication terminal according to the present invention includes an antenna configured as described above.

Hereinafter, exemplary embodiments of the present invention will be described with reference to the accompanying drawings.

1 is a perspective view illustrating an antenna configuration of a mobile communication terminal according to the present invention. First, referring to FIG. 1, a mobile communication terminal according to the present invention will be described in accordance with operations of a main circuit board (PCB) 2 and a main circuit board 2 provided in a main body. It includes an antenna for transmitting and receiving a signal of a predetermined band.

Thus, the structure of the antenna will be described in more detail. An antenna of the mobile communication terminal according to the present invention includes a radiating unit 10, a feeding unit 20 for feeding a signal to the radiating unit 10, and a signal transmitting end and a feeding unit 20 of the main circuit board 2 of the main body. And a second matching part 40 formed of a matching element connected between the first matching part 30 to perform impedance matching, the radiating part 10, and the main circuit board 2 of the main body.

Here, the radiator 10 is a metal radiator, which transmits a signal fed through the feeder 20 to the outside and receives a signal transmitted from the outside, thereby allowing frequency transmission and reception of a predetermined band or multiple bands. At this time, when transmitting and receiving a multi-band frequency, the radiator 10 is provided with a first region (10a) for transmitting and receiving a signal of a high frequency band, and a second region (10b) for transmitting and receiving a signal of a low frequency band, The signal fed through 20 is transmitted to the outside through the first region 10a and the second region 10b. At this time, the GSM network (880MHz, 960MHz) is representative of the low frequency band, PCS network (1.7GHz to 1.88GHz), WCDMA network (1.92GHz to 2.17GHz) and the like is a representative example of the high frequency band.

The power supply unit 20 is connected to the signal transmitting and receiving end of the main body circuit board 2, and serves to feed a signal transmitted from the main body circuit board 2 to the radiator 10. In this case, the first matching unit 30 performs impedance matching between the signal transmitting and receiving terminal of the main circuit board 2 and the power supply unit 20, and the signal matched through the first matching unit 30 is a power supply unit. The power is supplied to the radiating unit 10 through 20.

The second matching portion 40 is formed of an element connecting the point where the feed section 20 and the radiating section 10 are connected to the ground plane 2a of the main circuit board 2, and the radiating section 10 Short circuit). In this case, as the second matching part 40 is formed as a matching element, impedance matching is performed between the radiating part 10 and the ground plane 2a of the main circuit board 2 of the main body. Here, the second matching portion 40 is to be provided with at least one element of the coil (L) and the capacitor (C), which can be selectively implemented.

The antenna configured as described above is an antenna having a structure of a monopole antenna, but the second matching portion 40 is disposed between the power supply portion 20 of the antenna and the ground plane 2a of the main circuit board 2 of the antenna. By shorting the radiating section 10, it is possible to operate as a planar inverted F antenna (PIFA) circuit. Thus, by compromising the advantages and disadvantages of the monopole antenna and the planar inverted F antenna, it is possible to provide an antenna having a wider bandwidth and a higher gain.

FIG. 2 is a view referred to for describing an embodiment of a second matching unit according to the present invention. In particular, FIG. 2 is an exemplary view showing an embodiment according to the connection of a matching device provided in the second matching unit.

Here, as the matching element provided in the second matching unit 40, at least one element of the coil L and the condenser C is used as described in the above-described embodiment. In this case, FIGS. Impedance matching between the radiating section 10 and the ground plane 2a of the main circuit board 2 of the main body of the main circuit board 2 is performed by providing only the capacitor C as shown in FIG. In addition, as shown in (c) of FIG. 2, the coil L and the capacitor C may be connected in parallel, and as shown in (d), the coil L and the capacitor C may be connected in series. Also used as, the configuration of the matching element provided in the second matching portion 40 can be selectively implemented.

3 is a chart showing the standing wave ratio characteristics according to the antenna operation of the mobile communication terminal according to the present invention. In particular, by providing the second matching portion 40 between the radiating portion 10 and the ground plane 2a of the main circuit board 2, the Smith chart (showing measurement data for signals transmitted and received through the antenna) is shown. smith chart).

First, the Smith chart converts a rectangular coordinate system into circular coordinates based on one point. In this case, the Smith chart converts the relationship between the reflection coefficient and the load impedance into a complex circle formula and plots them step by step. The Smith chart is used to calculate standing wave ratios, reflection coefficients, and impedance matching circuits.

Thus, referring to FIG. 3, first, (a) illustrates a Smith chart in the case where the second matching portion 40 is not provided between the radiating portion 10 and the ground plane 2a of the main body circuit board 2. As shown, the trajectory from '1' to '5' rotates the center of the diagram, where the bandwidth becomes narrower as the size of the circle for this orbit rotating the center of the diagram becomes smaller and '1'. It can be seen that the reflection coefficient increases because the positions of the points from 'to' 5 are scattered widely from the center frequency.

3 (b) shows a Smith chart in the case where the second matching portion 40 is provided between the radiating portion 10 and the ground plane 2a of the main circuit board 2, ' As the size of the circle for the orbit that rotates the center of the diagram from 1 'to 5 increases, the bandwidth becomes wider and the impedance matching is better than that in (a). It can be seen that the reflection coefficient becomes smaller because the position is concentrated at the center frequency. Therefore, the antenna gain increases as the reflection coefficient at the center frequency in (b) with the second matching portion 40 becomes smaller than in (a) without the second matching portion 40. .

4 is a graph showing the standing wave ratio characteristics according to the operation of the antenna of the mobile communication terminal according to the present invention. FIG. 40 shows a relationship between voltage standing wave ratio (hereinafter referred to as " VSWR ") according to the frequency of a signal transmitted and received through an antenna.

Referring to FIG. 4, (a) shows the frequency f and VSWR when the second matching portion 40 is not provided between the radiating portion 10 and the ground plane 2a of the main body circuit board 2. (B) is a frequency (f) when the second matching portion 40 is provided between the radiating portion 10 and the ground plane (2a) of the main circuit board (2) and This graph shows the relationship to VSWR.

Here, VSWR is an index indicating the amount of energy input into a circuit or system, and refers to the ratio between the minimum and maximum values of the standing wave, which is a stationary wave generated when the traveling wave merges with the wave reflected by a certain boundary. do. At this point, if there is no reflection, there is no standing wave, so the ratio is 1, which is the best value, and if the amount of reflection is very large, the VSWR will go to infinity. In other words, as VSWR becomes close to 1, the transmission loss is lowered, thereby increasing the antenna gain.

Therefore, when comparing the graphs of FIGS. 4A and 4B, the transmission signal-to-transmission signal ratio is 2: 1. For example, the frequency band of '1' shown in the graph of FIG. Is 880MHz, '2' is 960MHz, '3' is 1.7GHz, '4' is 1.92GHz, '5' is 2.155GHz, '1' and '2' Corresponds to a band frequency of the GSM network, '3' to '4' areas correspond to the band frequencies of the PCS network, and '4' to '5' areas correspond to the band frequencies of the WCDMA network.

In this case, referring to FIG. 4A, when the second matching unit 40 is not provided between the radiating unit 10 and the ground plane 2a of the main circuit board 2, each frequency band is provided. The return loss coefficients are from '1' to '3.552', '2' to '1.9973', '3' to '6.5034', '4' to '3.0712' and '5' to '1.649'. On the other hand, referring to Figure 4 (b), when the second matching portion 40 is provided between the radiating portion 10 and the ground plane (2a) of the main circuit board 2 in each frequency band Return loss coefficients are '1' to '1.3759', '2' to '3.2426', '3' to '3.4506', '4' to '2.2792', and '5' to '1.9914'. That is, in the low frequency bands '1' and '2', the changes of (a) and (b) do not show much, but in the high frequency bands, especially in the '3' to '4' areas of the PCS network band, (a) and (b) ) Shows a large change.

Here, the VSWR is considered to be an ideal value when the minimum value of the standing wave is 1 and the maximum value is 4, in which the return loss coefficient of '3' in Fig. 4A is '6.5034', which is an ideal value of '4'. Since is exceeded, the signal sensitivity in the PCS frequency band corresponding to '3' is reduced. On the other hand, in FIG. 4 (b), since the return loss coefficient of '3' is '3.4506', which does not exceed the ideal value '4', the signal sensitivity in the PCS frequency band is improved than in (a), resulting in an antenna gain. It can be seen that high.

Therefore, the antenna according to the present invention, in addition to the first matching unit 30 for performing impedance matching between the power supply unit 20 and the main body circuit board 2, the radiating unit 10 and the main body circuit board (2). By providing a second matching section 40 that performs impedance matching between the ground planes 2a of the antenna, the PCS frequency band and the GPS frequency band are both covered with good characteristics.

As described above with reference to the drawings illustrated for the mobile communication terminal and its antenna according to the present invention, the present invention is not limited by the embodiments and drawings disclosed herein, the application within the scope of the technical spirit is protected Can be.

As described above, according to the present invention, by providing a matching element between the radiating part and the ground plane of the main circuit board of the main body to perform impedance matching to the short-circuit signal of the radiating part, the structure has a monopole antenna structure. As a circuit is operated by a planar inverted F antenna, the advantages and disadvantages of the monopole antenna and the planar inverted F antenna are compromised with each other, so that the bandwidth is high, the antenna gain is high, and the multiband signal transmission and reception is easy. .

Claims (7)

Radiating part; A feeding unit for feeding a signal to the radiating unit; A first matching unit performing impedance matching between the power feeding unit and a signal transmitting and receiving terminal of a main body circuit board which transmits and receives a signal; And And a second matching part formed of a matching element connected between the radiating part and the ground plane of the main circuit board of the main body. The method of claim 1, The matching element is an antenna, characterized in that at least one element of the coil (L) and capacitor (C). The method of claim 2, And the second matching part is formed by connecting the coil and the capacitor in series. The method of claim 2, And the second matching part is formed by connecting the coil and the capacitor in parallel. The method of claim 1, And the second matching part is operated as a shorting part of a planar inverted F-type antenna (PIFA). The method of claim 1, And the radiator transmits and receives a multi-band signal. A mobile communication terminal comprising an antenna according to any one of claims 1 to 6.

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