JP2005318333A - Antenna - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an antenna for multifrequencies enabling communication of transmission and a reception by an optimum sensibility by widening a resonance region, being a small size and being simple in the antenna for the multifrequencies incorporated into information terminal equipment, such as personal computer, PDA or the like. <P>SOLUTION: In the antenna for a second frequency, an element section 1 with a feeding point S1 given thereto and a ground plate 3 with a grounding point S2 given thereto are connected via a short-circuiting section 1b. In the antenna for the second frequency, the element section 1 is composed of a first radiation element 1a for a high frequency connected to the short-circuiting section 1b, and a second radiation element 1c for a low frequency which is extended in a folded-back shape, from the terminal A of the element 1c and in which an end is directed in a direction opposite to the first radiation element 1a for high frequency. In such an antenna for the second frequency, a sub-element 2 is formed without the feeding point, having a resonance point at the highest frequency, in parallel with the first radiation element 1a for high frequency. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a small antenna incorporated in an information terminal device such as a personal computer, PDA (portable information device), cellular phone, or VICS, and more particularly to a multi-frequency small antenna. More specifically, the present invention relates to an improvement in communication sensitivity of such a small antenna.

In recent years, PDAs equipped with wireless LAN or Bluetooth (short-range wireless data communication system) have become more and more demanding for higher bandwidth in order to obtain excellent communication quality along with the increase in frequency and size of antennas. Yes.
Although it is a printed antenna intended for larger size, as one measure to meet the demand for higher bandwidth, inductive dielectric elements with a shape similar to that of the radiating element are arranged in parallel to the narrow radiating element provided with a feeding member. It has been proposed to provide one or more in each. (See Patent Document 1)
In such an antenna, when a plurality of inductive dielectric elements are provided, a high bandwidth can be achieved over a wide range, and communication quality is ensured. However, this proposal only intends to increase the size of the antenna as described above, and does not recognize any solution as well as the opposite problem of “miniaturization”. In particular, the problem of “miniaturization” is particularly serious in a multi-frequency antenna that requires a plurality of radiating elements. Therefore, there is a need for a small antenna that can handle multiple frequencies and has excellent communication sensitivity over a higher band.

JP-A-6-69715

Therefore, an object of the present invention is to provide a small antenna excellent in communication sensitivity, especially a multi-frequency small antenna, in a multi-frequency antenna incorporated in an information terminal device such as a personal computer or a PDA. .

  The inventors of the present invention have paid attention to the effective use of a space formed in an antenna in which a radiating element portion and a ground plate that are parallel to each other are connected via a short-circuit portion. In addition, a non-powered narrow sub-element is arranged in the space, and as a result of considering the positions of the power feeding point and the ground point, the desired shape can be obtained over a high band without enlarging the outer shape of the antenna. Led to the realization of communication sensitivity.

As described above, according to the antenna of the present invention in which the location of the non-feed narrow sub-element and the positions of the feed point and the ground point are specified, the bandwidth can be extended over a wide band without expanding the antenna outer shape. It can be secured. As a result, the antenna communication sensitivity is improved in spite of the small size, so that a particularly remarkable effect is achieved that optimal communication is realized. At the same time, the antenna of the present invention can cope with multi-frequency antennas having three or more frequencies, so that the miniaturization can be realized while being a multi-frequency antenna. Furthermore, the antenna of the present invention can be applied to various types of antennas such as a three-dimensional antenna or a planar antenna, and is expected to be applied for various purposes.

Hereinafter, a dual-frequency antenna in which the resonance point of the sub-element is set to the maximum resonance frequency will be described with reference to the accompanying drawings.
FIG. 1 is a front view showing an example of the dual-frequency antenna of the present invention.
FIG. 2 is a perspective view when a feeding coaxial cable is attached to the antenna of FIG.
FIG. 3 is a diagram (graph) showing the frequency characteristics (frequency versus reflection loss characteristics) of the antenna of the present invention corresponding to two frequencies.
In FIGS. 1 and 2, (1) is a radiating element portion, which is illustrated as a so-called dual type composed of a first radiating element (1a) and a second radiating element (1c) each having a narrow width, In that case, (1b) is a narrow-width short-circuit portion that electrically connects the first radiating element (1a) and the ground plate (3). The first radiating element (1a) is formed in parallel with the rectangular ground plate (3) via the short-circuit portion (1b). Further, the second radiating element (1c) is formed in parallel with the ground plate (3) so as to be folded back into an L shape from the terminal end (A) of the radiating element (1a).
Here, (2) is a sub-element, and is arranged in parallel in parallel with the element (1a) in the space formed by the first radiating element (1a), the short-circuit portion (1b), and the ground plate (3). Has been. The sub-element (2) itself includes an induction element (2a) and a short-circuit element (2b) that electrically connects the induction element (2a) and the ground plate (3).
(4) is a coaxial cable for supplying power to the radiating element section (1), (L) is the length of the first radiating element (1a), (L1) is the length of the inductive element (2a), and (L2) is The distance between the first radiating element (1a) and the inductive element (2a), (L3) is the width of the inductive element (2a), and (S1) is a coaxial cable for supplying power to the first radiating element (1a) (4 ) Is a feeding point for connecting the inner conductors. This feeding point is preferably located in the middle in the longitudinal direction of the high-frequency first radiating element (1a). On the other hand, (S2) is an earth point for connecting the outer conductor of the cable (4). The earth point (S2) is formed at one end of the sub-element, that is, in the vicinity of the ground plate (3) to which the short-circuit element (2b) is connected. Accordingly, the coaxial cable (4) is connected so as to straddle the induction element (2a).
A characteristic of the present invention is that an antenna having excellent sensitivity is realized by the effect of expanding the bandwidth by adopting the sub-element (2) and specifying the feeding point-earth point.
This point will be described in detail below.
In the present invention, in order to improve the communication sensitivity by widening the bandwidth in the vicinity of the resonance point on the high frequency side of the two frequencies, the resonance frequency in the sub-element (2) is set to that of the first high-frequency radiation element (1a). It is important to set the maximum resonance frequency higher than the resonance frequency. Therefore, the length (L1) of the induction element (2a) of the sub-element (2) is made shorter than the length (L) of the first radiating element (1a) for high frequency as shown in the figure. As a result, the sub-element (2) resonates at a maximum resonance frequency that is higher than the high-frequency first radiating element (1a), so that the bandwidth of the antenna can be widened.
Specifically, the length (L1) of the sub-element (2) according to the resonance frequency of the high-frequency first radiating element (1a) so that a bandwidth of 100 MHz (megahertz) to 2 GHz (gigahertz) can be secured. May be adjusted to set the maximum resonance frequency. At this time, the sub-element (2) is for maximum frequency, the first radiating element (1a) is for high frequency, and the second radiating element (1c) is for low frequency. This aspect is an optimal means for further downsizing the antenna.
In the present invention, the distance (L2) between the first radiating element (1a) and the inductive element (2a) is also important. This is because if this distance (L2) is too wide, the electromagnetic field induced in the inductive element (2a) by the electromagnetic field fed to the first radiating element (1a) becomes weak, and the effect of widening the band is lost. In addition, if this interval is too narrow, unstable factors such as interference occur. Therefore, it is desirable to adjust (L2) in the range of 0.5 mm to 2.0 mm. The width (L3) of the sub-element (2) is preferably 0.5 mm to 3.0 mm in consideration of the strength of the induced electromagnetic field and the miniaturization of dimensions.

Next, the remaining configuration of the present invention will be described.
In the present invention, the length of each of the radiating elements (1a) and (1c) of the radiating element section (1) is set to approximately ¼ of the wavelength to be adopted, while the width is from 1 mm to Adopted appropriately from a range of 5 mm. Further, there is no particular limitation on the thickness, but about 0.1 mm to 1 mm is sufficient. The spacing between the inductive element (2a) and the ground plate (3) and the spacing between the first radiating element (1a) and the second radiating element (1c) are each 0.1 mm to ensure stable operation. As mentioned above, it is preferable that it exists in the range of 0.5-2 mm especially. If these intervals are less than 0.1 mm, unstable phenomena such as interference may occur.
As materials of these radiating elements (1a), (1c) and the induction element (2a), conductive metals such as white (white copper), copper, iron, and brass are desirable. In making the radiating element part (1) and the sub-element (2), a single plate of these metals is punched out, and is integrally punched with the short circuit part (1b), the short circuit element (2b), and the ground plate (3). Also good. Alternatively, it is also useful to obtain a desired antenna shape by etching the metal film in a state where a metal thin film such as a copper foil is attached to the flat insulating substrate.
As for the ground plate (3), in order to obtain stable antenna operation, the required minimum area (mm2) of the ground plate (3) satisfies λ / 4 * λ / 4 (λ is a wavelength) or more. Is desirable. Therefore, when more stable antenna operation is desired, it is desirable to increase the area as long as space permits. About the short circuit part (1b), as long as the function to connect a radiation | emission element part (1) and a ground board (3) is exhibited, the shape is arbitrary. Further, the shape of the short-circuit element (2b) of the sub-element (2) is arbitrary as long as it exhibits the function of connecting the ground plate (3), similarly to the short-circuit portion (1b).
As the feeding coaxial cable (4), a known high-frequency coaxial cable such as a fluororesin coating is employed. The end of the inner conductor of this cable (4) is connected to the feeding point (S1), and the outer conductor is connected to the earth point (S2). In order to connect the coaxial cable (4) to the feeding point (S1) and the earth point (S2), soldering or ultrasonic connection may be used.
The above aspect is an example in which the resonance point of the sub-element (2) is set to the maximum resonance frequency, but the present invention is not necessarily limited to this. The antenna itself is a so-called three-dimensional antenna in which the radiating element portion (1) and the ground plate (3) are not on the same plane as well as the flat antenna in which the radiating element portion (1) and the ground plate (3) are on the same plane. It goes without saying that it can be expanded to.
Furthermore, in the present invention, the resonance point of the sub-element (2) is set to the maximum resonance frequency to widen the band, but instead, the resonance point of the sub-element may be set near the low frequency, It is added that if the element (2) is set as another third frequency element, it is possible to cope with three frequencies in the mode of FIG.
Further, in the present invention, the resonance frequency of the element portion is set to the maximum resonance frequency, but instead, the single-frequency antenna in which the resonance frequency of the element portion is reduced to one or the resonance frequency of the element portion is further increased by one. Needless to say, it is possible to use an antenna with three or more frequencies.

Hereinafter, an example in which the antenna for two frequencies shown in FIGS.
1.
Preparation of radiation elements (1a), (1c), induction element (2a), short-circuit element (2b) and ground plate (3) First, a high-frequency first radiation element ( As 1a), an element having a length (L) of 16 mm and a width of 1.5 mm corresponding to a wavelength of 4.5 GHz was formed. Further, the length (L1) of the inductive element (2a) is 15 mm corresponding to a wavelength of 5.5 GHz which is a frequency higher than the resonant frequency 4.5 GHz of the first radiating element (1a) for high frequency, and its width (L3 ) Was 1.0 mm and the thickness was 0.4 mm. At that time, the first radiating element for high frequency (1a) and the induction element (2a) were arranged in parallel with an interval (L2) of 0.7 mm. Further, the induction element (2a) and the ground plate (3) were arranged in parallel with an interval of 2 mm. Further, the short-circuit portion (1b) of the element portion (1) has a length of 4.5 mm, a width of 3 mm, and a thickness of 0.4 mm, and the short-circuit element (2b) of the sub-element (2) has a length of 2 mm and a width of 3 mm. The thickness was 0.4 mm.
Next, an element having a length of 28 mm, a width of 1.5 mm, and a thickness of 0.4 mm corresponding to a wavelength of 2.4 GHz was formed as the low-frequency second radiating element (1c). At this time, the second radiating element (1c) extends in a folded shape from the end portion (A) of the first radiating element (1a) for high frequency, and the end portion is the end of the first radiating element (1a). It was formed so as to be directed in the opposite direction to the part (A). Further, the second radiating element for low frequency (1c) was arranged in parallel with an interval of 2 mm between the first radiating element for high frequency (1a).
The ground plate (3) was 32 mm long, 25 mm wide, and 0.4 mm thick.
Furthermore, the feeding point (S1) is 9 mm from the terminal end (A) of the first radiating element (1a) toward FIG. 1, and the position of the earth point (S2) is the sub-element toward FIG. In the vicinity of the start point of the short-circuit element (2b) in (2), the position was 2 mm from the upper end and 15 mm from the left end.
2. At the end of the antenna, a high-frequency coaxial cable coated with fluororesin (PFA) with an outer diameter of 1.13 mm and an inner conductor diameter of 0.24 mm is prepared as a feeding coaxial cable (4). The conductor was exposed. The cable (4) straddles the inductive element (2a) of the sub-element (2), the end of the inner conductor is at the feeding point (S1), and the outer conductor is at the ground point (S2). The antenna for the personal computer was obtained by connecting with solder.
When the bandwidth of this antenna was measured, as shown in FIG. 3, a band with a VSWR of 2 or less was sufficiently secured at 1500 MHz, and sufficient communication characteristics were obtained.
The present invention has been described above with an example of an antenna built in a personal computer, but it goes without saying that various applications are possible within the scope of the idea of the present invention.

Since the antenna of the present invention is compact and has stable communication characteristics, in addition to personal computers, various information terminal devices such as PDAs, mobile phones, or VICS, information home appliances having communication functions, and It can be used for automobile-related equipment as well.

It is a front view which shows an example of the antenna of this invention corresponding to 2 frequencies. It is a perspective view at the time of attaching the coaxial cable for electric power feeding to the antenna of FIG. It is a figure (graph) which shows the frequency characteristic (frequency versus reflection loss characteristic) of the antenna of this invention corresponding to 2 frequencies.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Radiation element part 1a High frequency 1st radiation element 1c Low frequency 2nd radiation element 1b Short circuit part 2 Subelement 2a Induction element 2b Short circuit element 3 Ground board
4 Coaxial cable A for feeding A Terminal portion L of the first radiating element (1a) Length L1 of the first radiating element (1a) Length L2 of the sub-element (2) First radiating element (1a) and sub-element (2) Interval L3 Width S1 of sub-element (2)
Feeding point S2 Earth point

Claims (7)

In the antenna in which the radiating element portion and the ground plate that are in parallel with each other are connected via a short-circuit portion,
A narrow sub-element having one end connected to the ground plate and not provided with a feeding point is arranged in parallel with the radiating element in a space formed by the radiating element portion, the short-circuit portion, and the ground plate; and ,
The feeding point is formed on the other side of the radiating element, and the ground point is formed in the vicinity of the ground plate to which one end of the sub-element is connected;
An antenna characterized by that. The antenna according to claim 1, wherein a resonance point of the sub-element is a maximum resonance frequency. The antenna according to claim 1 or 2, wherein a difference between a resonance frequency of the sub-element and a resonance frequency of the radiating element is in a range of 100 MHz to 2 GHz. The antenna according to any one of claims 1 to 3, wherein the parallel parallel interval is 0.5 mm to 2.0 mm. The antenna according to any one of claims 1 to 4, wherein the width of the sub-element is 0.5 mm to 3.0 mm. The antenna according to any one of claims 1 to 5, wherein the radiating element portion is connected to the short-circuited portion and has a narrow first radiating element; and extends in a folded shape from a terminal portion of the first radiating element. And a narrow-width second radiating element whose end portion is directed in a direction opposite to the end portion of the first radiating element. The dual-frequency antenna according to claim 6, wherein the first radiating element is for a high frequency and the second radiating element is for a low frequency.