1. Field of the Invention
The present invention relates to an array antenna on which a plurality of antenna elements for radiating radio waves are arranged generally in line, forming a linear array.
2. Description of the Related Art
There exist various kinds of conventionally known array antennas employing a configuration in which a plurality of antenna elements are formed on a substrate and the individual antenna elements are connected to secondary feeder lines which are arranged parallel to one another.
Referring to
More specifically, the antenna elements 2a–2i are arranged on the substrate 1 generally in line along a longitudinal (horizontal as illustrated in
In the aforementioned configuration, all of the antenna elements 2a–2i are arranged at regular intervals, whereby the array antenna radiates a high-intensity radio wave in a specified direction.
As shown in
In light of the foregoing, it is an object of the invention to provide an array antenna having desired directivity, in which antenna elements can be formed in a specific pattern on a substrate in an efficient way.
According to the invention, an array antenna includes a substrate, a plurality of antenna elements formed on a surface of the substrate in such a way that the antenna elements are arranged generally in a straight line, a plurality of secondary feeder lines individually connected to the antenna elements on sides thereof which are perpendicular to an arraying direction of the antenna elements, a primary feeder line to which the individual secondary feeder lines are connected parallel to one another, and a phase-inverting distributor inserted in the primary feeder line in an area located halfway along the length of the primary feeder line. In this array antenna of the invention, the sides of the antenna elements connected to the individual secondary feeder lines face a reference line which passes through the phase-inverting distributor perpendicular to the arraying direction of the antenna elements, the antenna elements are symmetrically arranged with respect to the reference line, and at least one of element-to-element intervals differs from the others.
In one feature of the invention, the primary feeder line and the secondary feeder lines are symmetrically arranged with respect to the aforementioned reference line. Alternatively, the phase-inverting distributor is located at a point of intersection of the aforementioned reference line and a second reference line passing through midpoints of the sides of the antenna elements which are parallel to the aforementioned reference line, the second reference line being perpendicular to the reference line, and the primary feeder line and the secondary feeder lines are symmetrically arranged with respect to the point of intersection of the reference line and the second reference line.
In the aforementioned configuration of the array antenna, the secondary feeder lines are connected to the respective antenna elements on the sides thereof facing the reference line on which the phase-inverting distributor is formed halfway along a longitudinal direction of the substrate. This means that sides of two antenna elements facing both longitudinal ends of the substrate are not connected to the secondary feeder lines. Thus, the antenna elements can be formed substantially all the way along the longitudinal direction of the substrate, from one longitudinal end thereof to the other. As will be later discussed in detail with reference to preferred embodiments of the invention, signals transmitted to the secondary feeder lines on left and right sides of the substrate are inverted in phase by the phase-inverting distributor. As a result, radio waves radiated from the antenna elements symmetrically arranged on the opposite sides of the reference line are not canceled out one another despite the fact that the secondary feeder lines supplies the signals to the antenna elements on the left and right sides of the substrate from opposite sides.
In the array antenna of the invention, one or more element-to-element intervals differ from the other element-to-element intervals as stated above. This means that the antenna elements can be arranged at desired intervals. This makes it possible to manufacture an array antenna having sharp directivity in a specific direction by properly determining the element-to-element intervals such that a desired radiation pattern (directivity) of the array antenna would be obtained as a result of mutual interference among the radio waves radiated from the individual antenna elements.
In another feature of the invention, conductor lines from the phase-inverting distributor to the individual antenna elements have varying impedances on each side of the reference line, each of the conductor lines including a portion of the primary feeder line and one of the secondary feeder lines.
In this array antenna of the invention, the conductor lines from the phase-inverting distributor to the individual antenna elements have varying impedances on each side of the reference line. This is equivalent to an array antenna configuration in which attenuators having varying amounts of attenuation are inserted in the conductor lines connected to the individual antenna elements. In this configuration, the individual antenna elements emit radio waves at intensities varying from one antenna element to next on each side of the reference line so that desired directivity is obtained as a result of mutual interference among the radio waves radiated from the individual antenna elements.
In still another feature of the invention, the interval between only those two antenna elements which are closest to the phase-inverting distributor differs from the interval between any two adjacent antenna elements.
Since the element-to-element interval differs only at a mid-length position of the substrate where the phase-inverting distributor is located according to this feature of the invention, the array antenna can be produced with a simple configuration by forming the antenna elements in a simplified arrangement pattern.
These and other objects, features and advantages of the invention will become more apparent upon reading the following detailed description in conjunction with the accompanying drawings.
An array antenna according to a first embodiment of the invention is now described with reference to
The antenna elements 2a–2t each have a rectangular shape in plan view and are formed in such a fashion that long sides of the antenna elements 2a–2t are aligned parallel to short sides of the substrate 1 and short sides of the antenna elements 2a–2t are aligned parallel to long sides of the substrate 1. These antenna elements 2a–2t formed on the substrate 1 are arranged at specified intervals along a longitudinal direction of the substrate 1 (parallel to the long sides of the substrate 1). The phase-inverting distributor 6 is formed in an area located generally on a vertical centerline, or a “reference line” passing between the antenna element 2i and the antenna element 2j shown by an alternate long and short dashed line in
The primary feeder line 4 is formed in a linear pattern extending leftward and rightward from the phase-inverting distributor 6 along the longitudinal direction of the substrate 1, that is, the direction in which the antenna elements 2a–2t are arrayed. Thus, as can be seen from
The antenna elements 2a–2i are connected to the first primary feeder line portion 4a by the secondary feeder lines 3a–3i, respectively. As depicted in
Similarly, the antenna elements 2j–2t are connected to the second primary feeder line portion 4b by the secondary feeder lines 3j–3t, respectively. As depicted in
The array antenna of the present embodiment thus structured has a bilaterally symmetrical configuration with respect to aforementioned reference line on which the phase-inverting distributor 6 is located, the reference line being perpendicular to the arraying direction of the antenna elements 2j–2t. More specifically, the array antenna has a pattern of electrodes and conductor lines forming the antenna elements 2a–2i, the secondary feeder lines 3a–3i and the first primary feeder line portion 4a on one side (left side as illustrated) of the reference line as well as a pattern of electrodes and conductor lines forming the antenna elements 2j–2t, the secondary feeder lines 3j–3t and the second primary feeder line portion 4b on the other side (right side as illustrated) of the reference line.
The phase-inverting distributor 6 distributes a signal fed through the outgoing line 5 to the first primary feeder line portion 4a and the second primary feeder line portion 4b with small loss with the signal transmitted to one of the primary feeder line portions 4a, 4b inverted in phase. Specifically, the phase of the signal transmitted to the second primary feeder line portion 4b is advanced or delayed by π radians with respect to the phase of the signal transmitted to the first primary feeder line portion 4a, for example.
Consequently, radio waves emitted from the antenna elements 2a–2i and the antenna elements 2j–2t which are symmetrically arranged on opposite sides of the reference line passing at right angles to the arraying direction of the antenna elements 2a–2t (
Here, the successive antenna elements 2a–2t are arranged at intervals (element-to-element distances) shown in
On the other hand, the secondary feeder lines 3a–3t have varying impedances so that the individual secondary feeder lines 3a–3t have predetermined amounts of attenuation as shown in Table 2. To achieve this, the secondary feeder lines 3a–3t are formed of conductor lines having specific thicknesses and widths, or impedance elements, such as resistors, are series-connected midway in the secondary feeder lines 3a–3t as appropriate.
Table 1 shows set values of the aforementioned element-to-element intervals Lab–Lst, and Table 2 shows the amounts of attenuation from the phase-inverting distributor 6 to the individual antenna elements 2a–2t including attenuation in the primary feeder line 4 and the respective secondary feeder lines 3a–3t.
As shown in Table 1, only the interval Lij between the antenna elements 2i and 2j differs from the other element-to-element intervals Lab–Lhi, Ljk–Lst in the array antenna of this embodiment.
Also, as shown in Table 2, conductor lines (including portions of the primary feeder line and the secondary feeder lines) connected to any two antenna elements located at symmetrical positions with respect to the aforementioned reference line have the same amount of attenuation, and the amounts of attenuation in these conductor lines increase with the distance from the phase-inverting distributor 6 to each successive antenna element in the array antenna of this embodiment.
As thus far discussed, only the interval Lij between the antenna elements 2i and 2j closest to the phase-inverting distributor 6 is made different from the other element-to-element intervals Lab–Lhi, Ljk–Lst and the amounts of attenuation in the conductor lines from the phase-inverting distributor 6 to the individual antenna elements 2a–2t are set to predetermined values in the array antenna of the first embodiment. According to this arrangement of the embodiment, it is possible to produce an array antenna having sharp directivity with a simple configuration, in which a large proportion of radio wave energy is radiated in approximately a central direction in a horizontal plane, perpendicular to a radiating surface of the array antenna, as shown in
As shown in
Furthermore, it is possible to obtain desired radiation characteristics by properly setting the amounts of attenuation for the individual secondary feeder lines 3a–3t. This means that an array antenna having the desired radiation characteristics (directivity) can be produced in an efficient way by using the substrate 1 having a given shape. Additionally, as the interval Lij between the antenna elements 2i and 2j at a central position of the substrate 1 along the arraying direction of the antenna elements 2a–2t, or the interval Lij between the antenna elements 2i and 2j closest to the phase-inverting distributor 6, is made different from the other element-to-element intervals Lab–Lhi, Ljk–Lst, the array antenna is obtained with a simplified antenna element arrangement pattern.
An array antenna according to a second embodiment of the invention is now described with reference to
The array antenna of the second embodiment has basically the same configuration as the array antenna of the first embodiment (refer to
Table 1 shows the intervals Lab-Lst between the successive antenna elements 2a–2t, and Table 2 shows the amounts of attenuation from the phase-inverting distributor 6 to the individual antenna elements 2a–2t including attenuation in the primary feeder line 4 and the respective secondary feeder lines 3a–3t.
As shown in Table 3, the interval Lab between the antenna elements 2a and 2b is equal to the interval Lst between the antenna elements 2s and 2t (Lab=Lst), the interval Lbc between the antenna elements 2b and 2c is equal to the interval Lrs between the antenna elements 2r and 2s (Lbc=Lrs), the interval Lcd between the antenna elements 2c and 2d is equal to the interval Lqr between the antenna elements 2q and 2r (Lcd=Lqr), the interval Lde between the antenna elements 2d and 2e is equal to the interval Lpq between the antenna elements 2p and 2q (Lpq=Lpq), the interval Lef between the antenna elements 2e and 2f is equal to the interval Lnp between the antenna elements 2n and 2p (Lef=Lnp), the interval Lfg between the antenna elements 2f and 2g is equal to the interval Lmn between the antenna elements 2m and 2n (Lfg=Lmn), the interval Lgh between the antenna elements 2g and 2h is equal to the interval Lkm between the antenna elements 2k and 2m (Lgh=Lkm), and the interval Lhi between the antenna elements 2h and 2i is equal to the interval Ljk between the antenna elements 2j and 2k (Lhi=Ljk). While the element-to-element intervals at any two symmetrical points with respect to the reference line passing through the phase-inverting distributor 6 are equal to each other as stated above, the interval Lij between the antenna elements 2i and 2j and the aforementioned element-to-element intervals on each side of the reference line are not necessarily equal to one another but are made unequal in this embodiment as indicated in Table 3.
Also, as shown in Table 4, conductor lines (including portions of the primary feeder line and the secondary feeder lines) connected to any two antenna elements located at symmetrical positions with respect to the aforementioned reference line have the same amount of attenuation, and the amounts of attenuation in these conductor lines increase with the distance from the phase-inverting distributor 6 to each successive antenna element in the array antenna of this embodiment.
With the aforementioned configuration of the second embodiment, it is possible to produce an array antenna having much sharper directivity (
The configuration of the second embodiment makes it possible to properly set the element-to-element intervals as well as the amounts of attenuation for the individual secondary feeder lines 3a–3t, so that a desired radiation pattern can be obtained from a wider range of radiation characteristics. In other words, an array antenna having the desired radiation characteristics (directivity) can be produced in an efficient way by setting the radiation characteristics within a wider range using the substrate 1 having a given shape. Furthermore, since the antenna elements 2a–2t can be arranged with more degrees of freedom in the second embodiment than in the first embodiment, it is possible to produce an array antenna having more optimized radiation characteristics.
While the array antennas of the foregoing embodiments are provided with 18 antenna elements each, the embodiments may be modified such that the array antenna is provided with any desired number of antenna elements according to required radiation characteristics and technical specifications of an apparatus for which the array antenna is used.
Furthermore, although the phase-inverting distributor 6 is formed in the area located generally on the reference line (vertical centerline) passing through a midpoint along the arraying direction of the antenna elements 2a–2t in the foregoing embodiments, the phase-inverting distributor 6 may be formed in any area selected along the arraying direction of the antenna elements 2a–2t according to required radiation characteristics.
Moreover, while the impedances of the secondary feeder lines 3a–3t are individually set such that the impedance of the conductor line from the phase-inverting distributor 6 to each of the antenna elements 2a–2t varies in a desired fashion in the foregoing embodiments, the impedance of the conductor line from the phase-inverting distributor 6 to each of the antenna elements 2a–2t may be varied by setting the impedance of a length of the primary feeder line 4 from the phase-inverting distributor 6 to a connecting point between the primary feeder line 4 and each of the secondary feeder lines 3a–3t to a desired value.
Number | Date | Country | Kind |
---|---|---|---|
2004-153591 | May 2004 | JP | national |
Number | Name | Date | Kind |
---|---|---|---|
4912481 | Mace et al. | Mar 1990 | A |
5790078 | Suzuki et al. | Aug 1998 | A |
6002370 | Mckinnon et al. | Dec 1999 | A |
6806845 | Fund et al. | Oct 2004 | B1 |
20050099358 | McCarrick | May 2005 | A1 |
20050219140 | Browne et al. | Oct 2005 | A1 |
20060055604 | Koenig | Mar 2006 | A1 |
Number | Date | Country |
---|---|---|
11-312909 | Nov 1999 | JP |
Number | Date | Country | |
---|---|---|---|
20050259028 A1 | Nov 2005 | US |