JP2008154013A - Antenna element - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a multifrequency antenna which is incorporated in an information terminal such as a personal computer or a PDA, and is excellent in communication sensitivity in a WAN band, has a simple structure and is suitable for downsizing. <P>SOLUTION: An open space formed between a front end part of a narrow width low frequency side radiating element and a ground plate is used to promote a capacitive coupling place in the space to thereby expand a WAN bandwidth. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a multi-frequency small antenna element incorporated in an information terminal device such as a personal computer, a PDA (portable information device), a mobile phone, or a VICS.

In recent years, PDAs and the like mounted on a wireless LAN or Bluetooth (short-range wireless data communication system) are increasingly required to be miniaturized as antennas have multiple frequencies. Among them, recently, there has been an increasing demand for WAN bands (824 MHz to 960 MHz and 1710 MHz to 2200 MHz) used particularly in mobile phones and the like.

By the way, in a WAN band, since the use frequency in a low frequency band is low, a low frequency side radiation element becomes unavoidable. For this reason, a proposal has been made to secure the element length as a structure in which the low-frequency radiation element is further folded outward (see, for example, Patent Document 1). However, when this folded structure is used, the antenna shape and dimensions tend to be large, and there is a problem that some devices cannot be incorporated.

JP 2006-311153 A

Accordingly, an object of the present invention is to provide a multi-frequency antenna element that is excellent in communication sensitivity in the WAN band, has a simple structure, and is suitable for downsizing.

  The present inventors utilize the open space formed between the tip of the narrow low-frequency side radiation element and the ground plate, and promote the capacitive coupling point in this space, thereby reducing the WAN bandwidth. Succeeded in spreading.

In the antenna element of the present invention, the band near the resonance point of the narrow low-frequency radiation element is obtained by the interaction with the tip of the narrow low-frequency radiation element, the open space, and the ground plate. As the width increases, the frequency characteristic (VSWR) is improved, thereby improving the communication sensitivity.

Hereinafter, a two-frequency antenna element in which the resonance point is set to the minimum resonance frequency using the above-described open space will be described with reference to the accompanying drawings.

FIG. 1 is a front view showing an example of the dual-frequency antenna element of the present invention.
FIG. 2 is a front view showing a preferred example of the dual-frequency antenna element of the present invention.
3 is a perspective view of the antenna when a feeding coaxial cable is attached to the antenna element of FIG.
FIG. 4 is a diagram (graph) showing the frequency characteristic (VSWR) of the antenna of FIG.

In FIG. 1, the radiating element section includes a narrow high frequency side radiating element (1) (hereinafter abbreviated as “high frequency element”) and a narrow low frequency side radiating element (2) (hereinafter referred to as “low”). It is shown as a so-called dual type consisting of “frequency element”. (3) is a short-circuit portion that electrically connects the high-frequency element (1) and the ground plate (4). The high-frequency element (1) is arranged in parallel with the rectangular ground plate (4) through the short-circuit portion (3), and further, the low-frequency element (1) passes through the connection portion (A) from the terminal end portion (B1) of the element (1). The frequency element (2) is folded back and arranged in parallel with the rectangular ground plate (4). At this time, the tip of the low frequency element (2) is directed in the reverse direction beyond the start end (B2) of the high frequency element (1). The tip at this time is indicated by (2a). (L) is the length of the tip (2a) that exceeds the starting end (B2).

Further, (W) is the width of the rectangular ground plate (4), and (H) is the height. (S1) is a feeding point for connecting the inner conductor of the coaxial cable for feeding power to the high-frequency element section (1), and is located in the middle of the high-frequency element (1). On the other hand, (S2) is an earth point for connecting the outer conductor of the cable, and is located at the upper edge of the ground plate (4) and facing the feeding point (S1).

In this way, the high frequency element (1) and the low frequency element (2) are opposed to each other in the width (W) direction in parallel with the width (W) direction of the rectangular ground plate (4). As a result, an open space (N) indicated by a satin finish is formed between the tip (2a) of the low-frequency element (2) and the rectangular ground plate (4) facing it. As is apparent from the drawing, this open space is a region where no other member is interposed.

According to the present invention, with respect to the open space (N) described above, the length (L) of the tip is at least one-third to one-third of the width (W) of the rectangular ground plate (4). It is confirmed that inductive coupling and capacitive coupling occur predominantly between the tip portion (2a) and the rectangular ground plate (4), thereby expanding the resonance bandwidth particularly in the low frequency range. It was. More specifically, in the equivalent circuit of resonance, inductive coupling (L coupling) in the width direction of the tip portion (2a) and capacitive coupling between the tip portion (2a) and the rectangular ground plate (4). LC resonance coupling consisting of (C coupling) occurs, and the resonance bandwidth in the low frequency range is widened.

Here, when the length (L) of the tip portion (2a) is less than one third of the width (W) of the rectangular ground plate (4), the capacitive coupling (C coupling) is not sufficient, and the antenna characteristics I cannot expect improvement. Further, if the value exceeds 2/3, the size in the width direction of the antenna increases, which is not preferable. The ground plate (4) may be wider than the width (W) shown in FIG. 1, but even in this case, the length (L) of the tip (2a) is the width (W). The standard is set to 1/3 to 2/3.

Specifically, the length (2a) of the tip (2a) according to the resonance frequency (0.9 GHz) of the low frequency element (2) so that 0.9 GHz is secured as the low frequency band of the WAN band. L) and by extension, the area of the open space (N) may be adjusted. The area (L1) between the tip end portion (2a) and the rectangular ground plate (4) is also involved in the area at this time. The distance (L1) is preferably 3 mm to 10 mm. If this distance (L1) is too small, interference occurs between the tip (2a) and the rectangular ground plate (4). Conversely, if it is too large, the above-described capacitive coupling (C coupling) is difficult to occur. There are concerns.

FIG. 2 shows a further developed form of the rectangular ground plate (4) of FIG. In this example, an L-shaped narrow sub-ground (4a) extending from the rectangular ground plate (4) is connected to the short-circuit portion (3). At this time, the long side portion of the sub-ground (4a) has the same length as that of the high-frequency element (1) and is in a parallel relationship, and therefore a slit (C) is formed between the two. An earth point (S2) is provided in the middle of the long side. This slit (C) causes slit resonance of the high-frequency element (1). FIG. 3 shows an antenna obtained by connecting a coaxial cable (5) to such an antenna element. The antenna itself is applied as a three-dimensional antenna or a planar antenna depending on the situation of the installation space.

In the present invention, the lengths of the high-frequency element (1) and the low-frequency element (2) are set to approximately ¼ of the wavelength to be adopted, or based on this ¼ length, What is necessary is just to set experimentally, considering the interaction between members. On the other hand, the width is appropriately selected from the range of 0.5 mm to 5 mm, and the thickness is appropriately selected from the range of 0.1 mm to 1 mm. At this time, if the connecting portion (A), which is a resistance component, is widened, the electrolytic strength is increased and the communication sensitivity is further improved. Specifically, the width may be set to be 4 mm or more and wider than the width of the high-frequency element (1).

Also, the distance between the high-frequency element (1) and the rectangular ground plate (4) (= the height of the short-circuited part (3)), the distance between the high-frequency element (1) and the low-frequency element (2) (= connecting part). The height (A) is preferably 1 mm or more and 5 mm or less in order to ensure stable operation as an antenna. The same applies to the distance between the sub-ground (4a) and the rectangular ground plate (4) in FIG.

The antenna element described above is obtained by punching a single metal plate such as white (brass), copper, iron, or brass. Alternatively, the metal film can be obtained by etching in a state where a metal thin film such as a copper foil is attached to a flat insulating substrate. Further, with respect to the ground plate (4), in order to obtain stable antenna operation, it is preferable that the necessary minimum area (mm2) satisfies λ / 4 * λ / 4 (λ = low frequency side) or more. Therefore, if more stable antenna operation is desired, the area may be increased as long as space permits.

As the feeding coaxial cable (5), a known high-frequency coaxial cable such as a fluororesin coating is employed. The end of the inner conductor of the cable (5) is connected to a feeding point (S1) in the high-frequency radiation element (1), and the outer conductor is a ground plate (4) or sub-ground (4a) facing the feeding point (S1). ) Connected to the earth point (S2) provided above. In order to connect the coaxial cable (5) to the feeding point (S1) and the earth point (S2), soldering or ultrasonic connection may be used.

Hereinafter, an example in which the antenna for two frequencies shown in FIGS. 2 to 3 is applied for use in a cellular phone using a WAN band (900 MHz / 1800 MHz) will be described.

1. Create the antenna element in Figure 2:
A single piece of Western white plate having a thickness of 0.4 mm was punched out to produce an integrated body corresponding to wavelengths of 900 MHz and 1800 MHz. The dimensions of each member at that time are as follows.
・
High-frequency element (1): length 40 mm, width 1.4 mm.
・
Low frequency element (2): length 80 mm, width 3 mm.
・
Rectangular ground plate (4): width (W) 80 mm, height (H) 80 mm.
Sub-ground (4a): long side length 40 mm, short side length 1 mm (= interval between rectangular ground plate (4) and sub-ground (4a)), width 1.4 mm.
Short-circuit part (3): Height 1.3 mm (= interval between the high-frequency element (1) and the long side part of the sub-ground (4a)), width 1.4 mm.
・
Connection part (A): Height 1.6 mm (= interval between the high-frequency element (1) and the low-frequency element (2)), width 3 mm.
The length (L) of the tip (a) of the low-frequency element (2): 40 mm (= half the width (W) of the rectangular ground plate (4)).
・
Distance (L1) between the tip (2a) and the ground plate (4): 6.7 mm.
The position of the feeding point (S1): substantially the center of the high-frequency element (1).
The position of the earth point (S2): a position facing the feeding point (S1) at the approximate center on the sub ground (4a).

2. As a coaxial cable (5) for completing the antenna shown in FIG. 3, a fluororesin (PFA) -covered high-frequency coaxial cable having an outer diameter of 1.13 mm and an inner conductor diameter of 0.24 mm is prepared. The conductor was exposed. By connecting the terminal end of the inner conductor to the feeding point (S1) and the outer conductor to the ground point (S2) by soldering, an antenna having the shape shown in FIG. 3 was obtained.

When the bandwidth of the obtained antenna was measured, as shown in FIG. 4, the band with VSWR of 2 or less was about 300 MHz at 824 MHz to 960 MHz on the low frequency side of the WAN band, and 700 MHz at 1710 MHz to 2200 MHz on the high frequency side. Sufficiently secured and sufficient communication characteristics were obtained.

Comparative example

In the above embodiment, the length (L) of the tip (2a) is set to 15 mm, and the width (W) of the rectangular ground plate (4) is reduced to 65 mm correspondingly, and L / W is reduced. The same experiment was repeated except that it was 0.23. In this case, a band with a VSWR of 2 or less is only 50 MHz at 824 MHz to 960 MHz on the low frequency side of the WAN band, and only 100 MHz at 1710 MHz to 2200 MHz on the high frequency side, and satisfactory communication characteristics are obtained. There wasn't.

The antenna of the present invention can be applied not only to the WAN band but also to the LAN band (2.5 GHz / 5 GHz). Therefore, in addition to cellular phones, various information terminal devices such as PDA or VICS can also communicate. It can also be used for information home appliances with functions, as well as automobile-related equipment.

The front view which shows an example of the antenna element for 2 frequencies of this invention. The front view which shows the preferable example of the antenna element for 2 frequencies of this invention. The perspective view of an antenna at the time of attaching the coaxial cable for electric power feeding to the antenna element of FIG. The figure (graph) which shows the frequency characteristic (VSWR) of the antenna of FIG.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Narrow width | variety high frequency side radiation | emission element 2 Narrow width | variety low frequency side radiation | emission element 2a The front-end | tip part 3 of a narrow width | variety low frequency side radiation | emission element (2) Short circuit part 4 Rectangular ground board 4a Subground 5 Coaxial for electric power feeding Cable A Connection B1 Terminal portion B2 of narrow high-frequency radiation element (1) Starting end L of narrow high-frequency radiation element (1) Length N of front end (2a) Open space W Rectangular ground Plate (4) width S1 Feed point S2 Earth point

Claims (5)

An antenna element in which a radiating element portion including a narrow high-frequency side radiating element and a narrow low-frequency side radiating element is arranged in parallel in the width direction within the width of a rectangular ground plate via a short-circuit portion. There,
The element portion includes a high-frequency side radiating element connected to the short-circuit portion, and extends from the front end portion of the high-frequency side radiating element so that the front end portion extends beyond the starting end portion of the high-frequency side radiating element. It consists of a low-frequency side radiating element that points to
The length of the tip of the low frequency side radiating element directed beyond the starting end of the high frequency side radiating element corresponds to one third or more of the width of the ground plate; and
An antenna element characterized in that an open space is formed so that capacitive coupling occurs between the tip portion and a ground plate facing the tip portion. The antenna element according to claim 1, wherein a distance between the tip portion and the rectangular ground plate is 3 mm to 10 mm. The antenna element according to claim 1 or 2, wherein a short-circuit portion is connected to an end of an L-shaped narrow sub-ground extending from the rectangular ground plate. The antenna according to claim 1 or 2, wherein an inner conductor of a coaxial cable is connected to the high-frequency radiation element, and an outer conductor of the cable is connected to the rectangular ground plate. The antenna according to claim 3, wherein an inner conductor of a coaxial cable is connected to the high-frequency radiation element, and an outer conductor of the cable is connected to the sub-ground.

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