[0001] The present invention relates to microstrip antennas and, more particularly, to a
microstrip antenna which corresponds to a plurality of frequency bands and is also
able to select the type of polarized wave. A conventional microstrip antenna will
now be explained with reference to Figs. 8 through 11.
[0002] A microstrip antenna 100 illustrated in Figs. 8 and 9 is constructed of a dielectric-made
substrate 101, a radiation electrode 102 formed on one main surface of the substrate
101, and a ground electrode 103 formed on the other main surface of the substrate
101. Moreover, a power-feeding through-hole 104 is provided at a position corresponding
to the radiation electrode 102 on the substrate 101. A connector 105 used for feeding
power to the radiation electrode 102 is inserted into and past the feeding through-hole
104 from the other main surface of the substrate 101. The connector 105 is electrically
connected to the radiation electrode 102 by means of solder 106a and is fixed to the
substrate 101 by means of solder 106a and 106b.
[0003] The microstrip antenna 100 constructed as described above receives the circularly
polarized wave, and the radiation electrode 102 is accordingly provided with degenerative-mode
separating portions 102a, as illustrated in Fig. 8.
[0004] A microstrip antenna 110 shown in Figs. 10 and 11 is configured of a dielectric-made
substrate 111, a radiation electrode 112 formed on one main surface of the substrate
111, and a ground electrode 113 disposed on the other main surface of the substrate
111. Further, a power-feeding through-hole 114 is provided at a position corresponding
to the radiation electrode 112 on the substrate 111. A connector 115 used for feeding
power to the radiation electrode 112 is inserted into and past the feeding through-hole
114 from the other main surface of the substrate 111. The connector 115 is electrically
connected to the radiation electrode 112 by means of solder 116a and is fixed to the
substrate 111 by means of solder 116a and 116b.
[0005] The microstrip antenna 110 configured as described above receives the linearly polarized
wave, and unlike the radiation electrode 102 of the microstrip antenna 100, the radiation
electrode 112 is accordingly free of regenerating separation portions, as shown in
Fig. 10.
[0006] In the above types of known microstrip antennas there is a great gap between the
frequency bands to be received by the respective antennas, and the polarized waves
to be received are also different. In order to receive the different frequency bands
simultaneously the following techniques are considered:
(1) arranging the two types of microstrip antennas side by side; and
(2) using a microstrip antenna of the type which is able to supply power to two radiation
electrode patterns formed on a single substrate.
[0007] In either of the techniques, however, the following problems are encountered. The
two radiation electrodes respectively corresponding to the different frequency bands
should be placed with an ample distance therebetween in order to avoid interference
between the frequency bands. Additionally, power-feeding means, such as a connector,
should be provided for each of the radiation electrodes, thereby hampering the miniaturization
of the antenna. EP 0655797A1 describes an antenna having a quarter wave resonance
strip and a parasitically excited strip resonant at a lower or upper frequency of
the antenna bandwidth. A location of a feed to the quarter wave resonance strip is
selected to provide a desired impedance match. The quarter wave resonance strip and
the parasitically excited strip are capacitively coupled by means of a plate overlapping
both the quarter wave resonance strip and the parasitically excited strip, said plate
being insulated from the two strips by means of an insulator substrate.
[0008] It is the object of the present invention to provide a miniaturized microstrip antenna
which copes with a plurality of frequency bands and is also able to select the type
of polarized wave.
[0009] This object is achieved by a microstrip antenna according to claim 1.
[0010] In order to achieve the above object, according to the present invention, there is
provided a microstrip antenna characterized by: a substrate; a first radiation-electrode
formed on one main surface of the substrate; at least one second radiation-electrode
formed on the periphery of the first radiation-electrode with a spacing between the
first and second radiation-electrodes; a ground electrode formed on the other main
surface of the substrate; a power-feeding means formed at a position corresponding
to the first radiation-electrode on the substrate; a through-hole formed at a position
corresponding to the second radiation-electrode on the substrate; and at least two
capacitive-coupling portions for capacitively coupling the first radiation-electrode
and the second radiation-electrode.
[0011] In the above-described microstrip antenna, the second radiation-electrode may be
formed generally in an "L" shape.
[0012] In the microstrip antenna, the capacitive-coupling portions are each formed in such
a manner that a first comb-like electrode projecting from the first radiation-electrode
to the second radiation-electrode may be interdigitated with a second comb-like electrode
projecting from the second radiation-electrode to the first radiation-electrode.
[0013] With the foregoing arrangements, the first radiation-electrode serves as a microstrip
antenna which corresponds to one frequency band. Moreover, the first radiation-electrode
is capacitively coupled to the second radiation-electrode so as to form another microstrip
line, thereby serving the function of a microstrip antenna which matches another frequency
band. Accordingly, a microstrip antenna which corresponds to a plurality of frequency
bands can be formed on a single substrate, and only one feeding through-hole is required
to feed power, thereby achieving the miniaturization of the antenna.
[0014] Moreover, the second radiation-electrode comprises at least one L-shaped radiation
electrode to enlarge the effective area of the microstrip antenna, thereby increasing
the gain of the antenna.
[0015] Further, since the capacitive-coupling portions are formed in a comb-like shape,
a high capacitance can be obtained only with the electrode pattern. This makes it
possible to decrease the thickness of the capacitive-coupling portions and also to
facilitate the adjustment of the capacitance by means such as trimming.
[0016] Additionally, by the use of chip capacitors having the desired capacitances as the
capacitive-coupling portions it is possible to obtain a microstrip antenna which is
able to receive the frequency bands with high precision and also to reliably select
the desired polarized wave.
[0017] Fig. 1 is a plan view illustrating the configuration of a microstrip antenna according
to the first embodiment of the present invention.
[0018] Fig. 2 is a sectional view taken along the line A-A of Fig. 1.
[0019] Fig. 3 illustrates the characteristics of the microstrip antenna according to the
first embodiment of the present invention: Fig. 3(a) is a Smith chart; and Fig. 3(b)
illustrates the characteristics of the return loss.
[0020] Fig. 4 is a plan view illustrating the configuration of a microstrip antenna according
to the second embodiment of the present invention.
[0021] Fig. 5 is a plan view illustrating the configuration of a microstrip antenna according
to the third embodiment of the present invention.
[0022] Fig. 6 is a plan view illustrating the configuration in which chip capacitors are
used as the capacitive-coupling portions of the microstrip antenna. Fig. 7 is a plan
view illustrating the configuration in which degenerative-mode separating portions
are provided for the first radiation-electrode of the microstrip antenna of the present
invention.
[0023] Fig. 8 is a plan view illustrating the configuration of a conventional microstrip
antenna.
[0024] Fig. 9 is a sectional view taken along the line B-B of Fig. 8.
[0025] Fig. 10 is a plan view illustrating the configuration of a conventional microstrip
antenna.
[0026] Fig. 11 is a sectional view taken along the line C-C of Fig. 10. Preferred embodiments
of the present invention will now be explained while referring to the drawings.
[0027] Referring to Figs. 1 and 2, a microstrip antenna 1 includes a dielectric-made substrate
11, a first radiation-electrode 12 formed on one main surface of the substrate 11,
second radiation-electrodes 13 and 14 formed on the periphery of the first radiation-electrode
12 with a spacing between the first electrode 12 and each of the second electrodes
13 and 14, a ground electrode 15 disposed on the other main surface of the substrate
11, a power-feeding through-hole 16 provided at a position corresponding to the first
radiation-electrode 12 on the substrate 11, a plurality of through-holes 17 provided
at positions corresponding to the second radiation-electrode 13 on the substrate 11,
and capacitive-coupling portions 18a and 18b for capacitively coupling the first radiation-electrode
12 and the respective second radiation-electrodes 13 and 14.
[0028] A connector 19, which serves as a coaxial line, for supplying power to the first
radiation-electrode 12 is inserted into and past the feeding through-hole 16 from
the other main surface of the substrate 11. The connector 19 is then electrically
connected to the first radiation-electrode 12 by means of solder 20a and is fixed
to the substrate 11 by means of solder 20a and 20b.
[0029] The second radiation-electrodes 13 and 14 are connected to the ground electrode 15
via the through-holes 17.
[0030] The first radiation-electrode 12 is formed generally in a square shape, and the second
radiation-electrodes 13 and 14 generally in a strip-like shape are respectively placed
to face the two sides of the first radiation-electrode 12. The capacitive-coupling
portions 18a and 18b are respectively formed in such a manner that first comb-like
electrodes 21 and 22 projecting from the first radiation-electrode 12 to the second
radiation-electrodes 13 and 14, respectively, are interdigitated with second comb-like
electrodes 23 and 24 projecting from the second radiation-electrodes, respectively,
to the first radiation-electrode 12. Accordingly, a capacitor is formed between the
first radiation-electrode 12 and each of the second radiation-electrodes 13 and 14,
thereby establishing capacitive coupling therebetween.
[0031] The first radiation-electrode 12, the second radiation-electrodes 13 and 14, and
the ground electrode 15 are all formed by etching metal film deposited on both main
surfaces of the substrate 11 or by printing and burning a conductive paste on both
main surfaces of the substrate 11.
[0032] The microstrip antenna 1 constructed as described above functions as an antenna in
which the first radiation-electrode 12 corresponds to one frequency band (higher frequency
band), and a combination of the first and second radiation-electrodes 12, 13 and 14
correspond to the other frequency band (lower frequency band).
[0033] The results of the test made on the first embodiment are as follows. Fig. 3(a) illustrates
a Smith chart illustrating the test results on the impedance characteristics of the
first embodiment, and Fig. 3(b) illustrates the characteristics of the return loss
of the first embodiment.
[0034] In this test, the distance between the center O of the first radiation-electrode
12 and the feeding through-hole 16 was determined to be L1, and the length of a side
of the first radiation-electrode 12 was determined to be L12. The feeding through-hole
16 was located at the position which was shifted from the center O toward the second
radiation-electrode 13 by an amount equal to the length L1 expressed by the following
equation:
and power was supplied to the first radiation-electrode 12 at the position of the
feeding through-hole 16. Further, the dielectric substrate 11 having a relative dielectric
constant of 10.5 was used, and the capacitances of the capacitive-coupling portions
18a and 18b were set to 3.0 pF and 2.5 pF, respectively. The side length L12 of the
first radiation-electrode 12 was set to λ
g1/2, and the distance L13 from the farthest edge of the first radiation-electrode 12
to that of the second radiation-electrode 13 was set to λ
g2/2. λ
g1 and λ
g2 designate the wavelengths of the higher frequency band and the lower frequency band,
respectively.
[0035] Figs. 3(a) and 3(b) show that double resonant characteristics in which resonances
are produced at f1 = 1.57 GHz and f2 = 2.56 GHz are obtained. It has thus been validated
that the microstrip antenna 1 of the present invention copes with a plurality of frequency
bands.
[0036] An explanation will now be given of a microstrip antenna 30 according to a second
embodiment of the present invention while referring to Fig. 4. Elements having the
same configuration as those of the microstrip antenna 1 shown in Fig. 1 are designated
by like reference numerals, and an explanation thereof will thus be omitted.
[0037] The microstrip antenna 30 differs from the microstrip antenna 1 in that a second
radiation-electrode 33 generally formed in an "L" shape is located to surround the
first radiation-electrode 12.
[0038] In this manner, the second radiation-electrode 33 is formed generally in an "L" shape
so as to increase the overall effective area including the first and second radiation
electrodes 12 and 33, thereby improving the gain of the microstrip antenna 30.
[0039] A microstrip antenna 40 according to a third embodiment of the present invention
will now be described with reference to Fig. 5. Elements having the same configuration
as those of the microstrip antenna 1 shown in Fig. 1 are designated by like reference
numerals, and an explanation thereof will thus be omitted.
[0040] The microstrip antenna 40 is different from the microstrip antenna 1 in that second
radiation-electrodes 43 and 44 are newly provided in addition to the electrodes 13
and 14 to surround all the four sides of the first radiation-electrode 12 which is
formed generally in a square shape, and that capacitive-coupling portions 18c and
18d are located between the first radiation-electrode 12 and the second radiation-electrodes
43 and 44, respectively.
[0041] The microstrip antenna 40 functions as an antenna in which the first radiation-electrode
12 corresponds to one frequency band, a combination of the first radiation-electrode
12 and the second radiation-electrodes 13 and 14 deals with another frequency band,
and a combination of the first radiation-electrode 12 and the second radiation-electrodes
43 and 44 copes with still another frequency band.
[0042] In this microstrip antenna 40, as well as in the antenna 30 of the second embodiment,
the second radiation-electrodes 13 and 14 may be combined to form a generally "L"
shape, and the second radiation-electrodes 43 and 44 may also be combined to form
a generally "L" shape, though such a modification is not shown.
[0043] In the microstrip antennas described in the first through third embodiments, the
first radiation-electrode is capacitively coupled to the second radiation-electrodes
via the respective capacitive-coupling portions. The locations of the capacitive-coupling
portions may be displaced, and the comb-like electrodes forming the capacitive-coupling
portions may be trimmed, thereby readily adjusting the lower frequency band to be
received and also selecting the polarized wave on the lower frequency side.
[0044] For example, in the microstrip antenna 1 of the first embodiment, the locations of
the two capacitive-coupling portions 18a and 18b are displaced and the capacitances
of the respective portions are differentiated, thereby causing a phase difference
θ between the resonance produced by capacitive coupling of the capacitive-coupling
portion 18a and that of the capacitive-coupling portion 18b. When the phase difference
θ approaches 90°, a circularly polarized wave is produced in the lower frequency side.
On the other hand, when the phase difference θ approaches 0°, a linearly polarized
wave is generated in the lower frequency side. In Fig. 3(a), illustrating the test
results of the first embodiment, there is shown a constriction indicated by V of the
Smith chart of the lower frequency band f1; this constriction represents the state
in which a circularly polarized wave is generated in the lower frequency side. In
other words, in this microstrip antenna 1, the positions and the capacitances of the
capacitive-coupling portions 18a and 18b are set so that a phase difference θ between
the resonance produced by capacitive coupling of the capacitive-coupling portion 18a
and that of the capacitive-coupling portion 18b is approximately 90°.
[0045] The capacitive-coupling portions formed in the comb-like shape can be simultaneously
fabricated with the first and second radiation-electrodes. This makes it possible
to easily form the capacitive-coupling portions and to also make the thickness of
the portions equal to that of the electrodes.
[0046] Fig. 6 shows an example using chip capacitors 38. In this case, since chip capacitors
having the desired capacitances can be selected, it is possible to readily and correctly
fabricate an antenna which copes with the required frequency bands and required polarized
wave. By virtue of this modification, the process steps of adjusting the frequency
and re-selecting the polarized wave are unnecessary. It should be noted that the elements
shown in Fig. 6 other than the chip capacitors 38 are the same as those of the microstrip
antenna 30 explained in the second embodiment, and an explanation thereof will thus
be omitted.
[0047] The mode of the capacitive-coupling portions is not restricted to the foregoing embodiments,
but may be modified according to the purpose or the use of the microstrip antenna.
For example, the capacitive-coupling portions, which are placed where the first and
second radiation-electrodes can be capacitively coupled, may be configured in a laminated
structure in which a dielectric layer is interposed between the first radiation-electrode
and the second radiation-electrodes, though such a modification is not shown.
[0048] Further, the first radiation-electrode 12 of each embodiment may be configured, as
illustrated in Fig. 7, to have degenerative-mode separating portions 12a so as to
select the type of polarized wave of the higher frequency side to be received by the
first radiation-electrode 12. It should be noted that the elements shown in Fig. 7
other than the degenerative-mode separating portions 12a are the same as those of
the microstrip antenna 1 of the first embodiment, and an explanation thereof will
thus be omitted.
[0049] In this manner, according to the microstrip antenna of the present invention, the
first radiation-electrode which copes with one frequency band (higher-frequency band)
is able to set the type of polarized wave, and a combination of the first and second
radiation-electrodes is also capable of selecting the type of polarized wave.
[0050] Although in the foregoing embodiments the first radiation-electrode is formed generally
in a square shape, it may be formed generally in a circular shape.
[0051] In the foregoing embodiments, the second radiation-electrodes are connected to the
ground electrode via a plurality of through-holes. If, however, the second radiation-electrodes
are grounded in a high frequency band, the number of through-holes may be determined
as required.
[0052] As is seen from the foregoing description, the microstrip antenna of the present
invention offers the following advantages. The first radiation-electrode serves as
a microstrip antenna which corresponds to one frequency band. Moreover, the first
radiation-electrode is capacitively coupled to the second radiation-electrodes so
as to form another microstrip line, thereby serving the function of a microstrip antenna
which copes with another frequency band. Accordingly, a microstrip antenna which matches
a plurality of frequency bands can be formed on a single substrate, and only one feeding
through-hole is required to feed power, thereby achieving the miniaturization of the
antenna.
[0053] Moreover, the second radiation-electrodes are formed generally in an "L" shape so
as to enlarge the effective area of the microstrip antenna, thereby increasing the
gain of the antenna.
[0054] Further, since the capacitive-coupling portions are formed in a comb-like shape,
a high capacitance can be obtained only with the electrode pattern. This makes it
possible to decrease the thickness of the capacitive-coupling portions and also to
facilitate the adjustment of the capacitance by means such as trimming, thereby receiving
the frequency bands with high accuracy and enabling the selection of the type of polarized
wave.
[0055] Additionally, by the use of chip capacitors having the desired capacitances as the
capacitive-coupling portions it is possible to obtain a microstrip antenna which is
able to receive the frequency bands with high precision and also to select the desired
polarized wave.