Communications: radio wave antennas – Antennas – Slot type
Reexamination Certificate
2003-04-24
2004-11-30
Chen, Shih-Chao (Department: 2821)
Communications: radio wave antennas
Antennas
Slot type
C343S7000MS
Reexamination Certificate
active
06825816
ABSTRACT:
BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates to a slot line planar antenna, and more particularly to a two-element and a multi-element slot line antenna which are simple in configuration and have a plurality of arrayed slot line antenna elements that are excited in phase.
2. Description of the Related Arts
Planar antennas are widely used in, for example, radio communications and satellite broadcasting because of their characteristics of ease in machining, small size, light weight, and the like. Planar antennas are classified into a microstrip line type, a slot line type, and the like. Generally, the microstrip line planar antenna is often used since it has a simple feed system structure, good radiation characteristics, and the like.
However, the microstrip line planar antenna is disadvantageous in a narrow frequency band in which it can operate a relatively low antenna gain, and difficulties in suppressing orthogonal components from antenna elements and feed system. From the foregoing, the slot line planar antenna has gained the spotlight because it has wide band frequency characteristics and less radiations of orthogonal components from antenna elements themselves, as compared with the microstrip line planar antenna.
Exemplary configurations of conventional slot line planar antennas will be described with reference to
FIGS. 1A
,
1
B,
2
A,
2
B,
3
A,
3
B,
4
A,
4
B and
5
. In the accompanying drawings, dotted portions on plan views represent areas over which conductors are formed on a first main surface of a substrate. Solid black areas in cross-sectional views represent cross-sections of conductors.
Each of illustrated slot line planar antennas comprises a substrate
1
made of a dielectric material or the like; antenna element
3
through which electromagnetic waves are transmitted or received, and feed systems
4
a
to
4
c
for transmission and reception disposed on substrate
1
. Antenna element
3
is formed by routing a so-called slot line, which is a linear or loop-shaped open line, in conductor
2
formed on one main surface of substrate
1
. A resonant frequency on an electric field plane depending on the length of the slot line is defined as a frequency at which electromagnetic waves are transmitted and received through antenna element
3
. Generally, the length of the slot line is set to &lgr;/2, where &lgr; is the wavelength of the transmission and reception frequency.
In slot line antenna element
3
, the slot line is a balanced transmission line, and an electric field plane is produced in a direction orthogonal to an electric field which is excited in the same direction alternately between the conductors on both sides of the open line, so that a complete standing wave of electromagnetic field is generated in the slot line. Generally, a cross section in the electric field direction, i.e., in the width direction of the open line is referred to as an electric field plane (E plane), and a cross section in the magnetic field direction, i.e., in the lengthwise direction of the open line is referred to as a magnetic field plane (H plane).
In the slot line planar antenna, since the slot line is formed on one main surface of substrate
1
on which conductor
2
is formed to produce the electromagnetic field plane on the same surface, less orthogonal components are produced in the electric field plane and magnetic field plane, as compared with a microstrip line planar antenna in which an electric field is excited between both main surfaces of a substrate.
In a slot line planar antenna, a microstrip line or a coplanar line, for example, is selected for a feed system when slot line antenna element
3
is linear. A slot line planar antenna illustrated in
FIGS. 1A and 1B
comprises linear slot line antenna element
3
and a feed system based on microstrip line
4
a
. Microstrip line
4
a
, which constitutes the feed system, is formed on the other main surface of substrate
1
such that it is in close proximity to one end of slot line antenna element
3
in the lengthwise direction, and extends in a direction orthogonal to the lengthwise direction of antenna element
3
. Microstrip line
4
a
is electromagnetically coupled to slot line antenna element
3
.
A slot line planar antenna illustrated in
FIGS. 2A and 2B
comprises a linear slot line antenna element
3
and a feed system based on coplanar line
4
b
. Coplanar line
4
b
is formed on one main surface of substrate
1
such that it extends from the center of slot line antenna element
3
in a direction orthogonal to the lengthwise direction of slot line antenna element
3
.
When slot line antenna element
3
is formed in a loop shape as illustrated in
FIGS. 3A and 3B
, slot line
4
c
, for example, is selected for a feed system. In this event, feed slot line
4
c
is routed on one main surface of substrate
1
, and is connected to one end side of a corner of the slot line which constitutes antenna element
3
.
In the respective slot line planar antennas described above, electromagnetic waves, i.e., high frequency signals, are propagated from the feed system, which may be a microstrip line, a coplanar line or a slot line, to slot line antenna element
3
or from slot line antenna element
3
to the feed system upon transmission and reception.
Since these planar antennas each provide a low antenna gain with single slot line antenna element
3
, a plurality of slot line antenna elements
3
are arranged to form, for example, an array antenna for improving the antenna gain.
FIG. 4
illustrates an array antenna which comprises a plurality of linear slot line antenna elements
3
, for example, arranged one-dimensionally on one side of microstrip line
4
a
which serves as a feed system.
FIG. 5
illustrates an array antenna using loop-shaped slot line antenna elements
3
which are arranged on both sides of coplanar line
4
b
, which serves as a feed system, through short feed slot line. Pairs of slot line antenna elements
3
are arranged in the longitudinal direction of coplanar line
4
b.
However, either of the foregoing slot line array antennas has slot line antenna elements
3
simply arranged one-dimensionally along the feed system, which is made of the microstrip line or coplanar line, formed on one main surface of substrate
1
. It is difficult to two-dimensionally arrange such antenna elements to form a multi-element array antenna.
When a two-dimensional array antenna is implemented by placing two or two pairs or more of slot line antenna elements
3
not only along the longitudinal direction of a feed system but also in a direction orthogonal to which the feed system extends, the feed system will interlace on one main surface of substrate
1
, causing difficulties in providing a multi-element array antenna. In this event, even if the feed system drawn about to arrange antenna elements in two-dimensional directions, the respective slot line antenna elements will be fed from a feed end with different feed lengths from one another, thereby making it difficult to excite the respective slot line antenna elements in phase, with a resulting reduction in the directivity. Of course, the reduction in the directivity can be avoided if the feed system is set such that the antenna elements are matched in phase, in which case, however, complicated designing is imposed for the feed systems. In addition, when microstrip lines alone are used for the feed system in an array antenna, orthogonal components are necessarily produced and can be difficult to suppress.
While an existing two-dimensional multi-element antenna array employs a feed system comprised of tubular metal waveguides such as radial lines or the like, the use of the tubular waveguides results in a three-dimensional structure, inevitably causing a large sized antenna array.
As described above, a planar antenna having slot line antenna elements is practically limited to a one-dimensional array antenna in actuality due to a feed system based on a microstrip line, a coplanar line or a slot line. Therefore, a demand exists f
Aikawa Masayoshi
Asamura Fumio
Nishiyama Eisuke
Oita Takeo
Chen Shih-Chao
Katten Muchin Zavis & Rosenman
Nibon Dempa Kogyo Co., Ltd.
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