This application is based upon and claims the benefit of priority from the prior Japanese Patent Application No. 2007-176503 filed on Jul. 4, 2007; the entire contents of which are incorporated herein by reference.
1. Field of the Invention
The present invention relates to an antenna device, and in particular to an antenna device having no less than two antenna elements.
2. Description of the Related Art
There is a trend that radio apparatus like mobile phones are equipped with not only so called a cellular-type mobile communication system but also various kinds of radio systems such as a wireless local area network (WLAN), the global positioning system (GPS), a radio identification system (RFID), a terrestrial digital television system and so on. It is anticipated that the above trend continues to grow, and that the radio apparatus will increasingly have multiple uses and multiple functions.
In response to advances in multiple uses and multiple functions of the radio apparatus, features of multiple resonance and broader frequency ranges are increasingly required of antenna devices provided in the radio apparatus. Meanwhile, downsizing and compactness are also required of the antenna devices from a viewpoint of improvement of designs and downsizing of the radio apparatus. In order to meet the above requirements conflicting to each other, the radio apparatus has to be equipped with an antenna device adapted for plural radio systems.
Configuration of such an antenna device may be divided broadly into two types of approaches. One of the approaches is a configuration where plural antenna elements (maybe including a parasitic element) having different resonant frequencies one another are combined, commonly fed by and distributed to plural systems via an antenna sharing device such as a switch or a duplexer.
Another one of the approaches is a configuration where plural antennas are arranged close to each other in a space-efficient manner, and each of the antennas is separately fed by an associated system.
In the configuration using the antenna sharing device, an isolation characteristic of the antenna sharing device dominates isolation among the systems different one another. In order to compensate for shortage of the isolation of the antenna sharing device, another device such as a band-pass filter may be needed. Consequently, increased insertion losses of the antenna sharing device and the filter may cause basic performance such as transmitter power or receiver sensitivity to be degraded.
The configuration where each of plural antennas is separately fed by an associated system is advantageous to basic performance of radio apparatus, as there is no need to think of insertion losses of antenna sharing devices and filters. Meanwhile, there is a problem that isolation may hardly be assured as the antennas are arranged spatially close one another.
For such a problem, conventional antenna devices have been proposed so that isolation may be assured, as disclosed in Japanese Patent Publication of Unexamined Application (Kokai), No. 2003-332840 and No. 2005-198245.
More specifically, the invention of the antenna device disclosed in JP 2003-332840 was applied by the applicant of this application so as to reduce a cross coupling between antennas of an antenna device arranged on a same grounded conductive plate and to reduce leakage of electromagnetic waves from a transmitting antenna to a receiving antenna. The antenna device is provided with a plate-like short-circuiting element on and almost perpendicular to the grounded conductive plate between feed portions of the antennas, and configured to block views between the feed portions for solving the above problems.
The antenna device disclosed in JP 2005-198245 is configured that one of two antenna elements is a half wavelength long with a grounded end so as to work equivalently to a loop antenna of a wavelength long and to suppress resonance occurring on a ground plane. It is mentioned that even if another one of the antenna elements is excited at a nearby frequency, a coupling between the antenna elements may be suppressed as antenna current distribution is small near a feed portion of the equivalent loop antenna.
The antenna device disclosed in JP 2003-332840 by the applicant of this application is configured to have the plate-like short-circuiting element perpendicular to the grounded conductive plate so as to isolate between the antennas. Such a configuration may not be very suitable for a small sized radio apparatus such as a mobile phone which is required to be small and thin.
The antenna device disclosed in JP 2005-198245 is on an assumption that frequency bands of use of the antenna elements are close to each other. It is thus restricted to apply such a configuration to broad multiple uses and multiple functions of radio apparatus.
Accordingly, an object of the present invention is to provide an antenna device including plural antenna elements and configured to assure isolation among the antenna elements to be ready for broad multiple uses and multiple functions of radio apparatus.
To achieve the above object, according to one aspect of the present invention, an antenna device provided in a radio apparatus having a printed circuit board includes a first antenna element and a second antenna element. The first antenna element is configured to be fed at a first feed portion provided on the printed circuit board. The first antenna element is configured to be grounded at a first short-circuit portion provided on the printed circuit board. The second antenna element is configured to be fed at a second feed portion provided on the printed circuit board. The second antenna element is configured to be grounded at a second short-circuit portion provided on the printed circuit board. The second feed portion is located farther from the first feed portion than from the first short-circuit portion, farther than the first short-circuit portion is from the first feed portion, farther from the first short-circuit portion than from the second short-circuit portion, and farther than the second short-circuit portion is from the first short-circuit portion.
Hereinafter, embodiments of the present invention will be described in detail. In following descriptions, terms like upper, lower, left, right, horizontal or vertical used while referring to a drawing shall be interpreted on a page of the drawing unless otherwise noted. Besides, a same reference numeral given in no less than two drawings shall represent a same member or a same portion.
A first embodiment of the present invention will be described with reference to
The antenna device 10 has a first antenna element 11 and a second antenna element 12. The PCB 1 may be formed not only by a single board but by plural boards.
The first antenna element 11 is configured to be fed at a first feed portion 13 provided on the PCB 1 and is short-circuited to a ground circuit of the PCB 1 at a first short-circuit portion 14 provided on the PCB 1 so as to be grounded. The first antenna element 11 has a tip which is an open end 17.
The second antenna element 12 is configured to be fed at a second feed portion 15 provided on the PCB 1 and is short-circuited to the ground circuit of the PCB 1 at a second short-circuit portion 16 provided on the PCB 1 so as to be grounded.
The antenna device 10 has two features of configuration for improving isolation between the first antenna element 11 and the second antenna element 12. A first one of the features is that the first antenna element 11 and the second antenna element 12 are grounded at the first short-circuit portion 14 and the second short-circuit portion 16, respectively.
The above first feature may produce an effect that the isolation may be improved in comparison with a case where the first antenna element 11 or the second antenna element 12 were of an open-ended monopole type with no short-circuit portion. The above effect has been verified by simulation and will be explained, combined with a second embodiment of the present invention, later with reference to
A second one of the features is that each of the first short-circuit portion 14 and the second short-circuit portion 16 is arranged between the first feed portion 13 and the second feed portion 15.
More specifically, a distance between the first short-circuit portion 14 and the first feed portion 13 is smaller than a distance between the first feed portion 13 and the second feed portion 15. Besides, a distance between the first short-circuit portion 14 and the second feed portion 15 is smaller than the distance between the first feed portion 13 and the second feed portion 15. That is, the first short-circuit portion 14 is located between the first feed portion 13 and the second feed portion 15, and not very far from a straight line joining the first feed portion 13 and the second feed portion 15.
In other words, the second feed portion 15 is located farther from the first feed portion 13 than from the first short-circuit portion 14, and farther than the first short-circuit portion 14 is from the first feed portion 13.
Then, a distance between the second short-circuit portion 16 and the first short-circuit portion 14 is smaller than a distance between the first short-circuit portion 14 and the second feed portion 15. Besides, a distance between the second short-circuit portion 16 and the second feed portion 15 is smaller than the distance between the first short-circuit portion 14 and the second feed portion 15. That is, the second short-circuit portion 16 is located between the first short-circuit portion 14 and the second feed portion 15, and not very far from a straight line joining the first short-circuit portion 14 and the second feed portion 15.
In other words, the second feed portion 15 is located farther from the first short-circuit portion 14 than from the second short-circuit portion 16, and farther than the second short-circuit portion 16 is from the first short-circuit portion 14.
An arrangement of the first feed portion 13, the first short-circuit portion 14, the second short-circuit portion 16 and the second feed portion 15 along the upper side of the PCB 1 and almost on a single straight line as shown in
The above feed portions and the short-circuit portions may not be arranged on a single straight line as shown in
As shown in
The second antenna element 12a is configured to be fed at the second feed portion 15 provided on the PCB 1 and is short-circuited to the ground circuit of the PCB 1 at the second short-circuit portion 16 provided on the PCB 1 so as to be grounded, in a same manner as described above with respect to the second antenna element 12.
The second antenna element 12a is formed by a round-trip line folded back at a fold portion 18. The first feed portion 13, the first short-circuit portion 14, the second feed portion 15 and the second short-circuit portion 16 are in a same positional relationship as explained with respect to the antenna device 10 as shown in
The antenna device 10a has the first and second features same as the antenna device 10 has, for improving isolation between the first antenna element 11 and the second antenna element 12a. Besides, the first antenna element 11 is formed in a way that the open end 17 is directed leftwards and the second antenna element 12a is formed in a way that the fold portion 18 is directed rightwards. That is, the first antenna element 11 and the second antenna element 12a are formed in a way that the open end 17 and the fold portion 18 are directed to go away from each other.
The first antenna element 11 is configured to be a so-called inverted-F antenna. If the first antenna element 11 is fed, a relatively high voltage is distributed at and around the open end 17. The second antenna element 12a is configured to be a folded monopole antenna. If the second antenna element 12a is fed, a relatively high voltage is distributed at and around the fold portion 18.
As the open end 17 and the fold portion 18 where relatively high voltages are distributed are directed to go away from each other, a voltage-coupling between the first antenna element 11 and the second antenna element 12a may be suppressed, and isolation between the first antenna element 11 and the second antenna element 12a may be improved.
Due to limited mounting space of the radio apparatus, it may be difficult to locate the open end 17 of the first antenna element 11 further left to a left side of the PCB 1. In such a case, the first antenna element 11 is formed directed away from the second antenna element 12a near the upper side of the PCB 1, and the open end 17 is located near a left end of the upper side of the PCB 1.
The second antenna element 12b is configured to be fed at the second feed portion 15 provided on the PCB 1 and is short-circuited to the ground circuit of the PCB 1 at the second short-circuit portion 16 provided on the PCB 1 so as to be grounded, in a same manner as described above with respect to the second antenna element 12. The first feed portion 13, the first short-circuit portion 14, the second feed portion 15 and the second short-circuit portion 16 are in a same positional relationship as explained with respect to the antenna device 10 as shown in
In order to improve isolation between the first antenna element 11 and the second antenna element 12b, the antenna device 10b has the first and second features which are same as the antenna device 10 has. Besides, a portion of the first antenna element 11 near the first feed portion 13 and a portion of the second antenna element 12b near the second feed portion 15 are formed almost perpendicular to each other.
As the portion of the first antenna element 11 near the first feed portion 13 and the portion of the second antenna element 12b near the second feed portion 15 are formed almost perpendicular to each other, a current-coupling between the first antenna element 11 and the second antenna element 12b may be suppressed, and the isolation between the first antenna element 11 and the second antenna element 12b may be improved. The antenna device 10a shown in
According to the first embodiment of the present invention described above, the antenna device having plural antenna elements may be configured to select the positional relationship of the feed portions and the short-circuit portions and configured to select the positional relationship between the antenna elements associated with the high-and-low voltage or current distribution for improving the isolation between the antenna elements.
A second embodiment of the present invention will be described with reference to
The first antenna element 21 is configured to be fed at a first feed portion 23 provided on the PCB 1 and is short-circuited to a ground circuit of the PCB 1 at a first short-circuit portion 24 provided on the PCB 1 so as to be grounded. The first antenna element 21 has a tip which is an open end 27. Although the first antenna element 21 is a same as the first antenna element 11 of the first embodiment, each portion of the first antenna element 21 is given an updated reference numeral.
The second antenna element 22 is configured to be fed at the second feed portion 25 provided on the PCB 1 and is short-circuited to the ground circuit of the PCB 1 at the second short-circuit portion 26 provided on the PCB 1 so as to be grounded.
The second antenna element 22 is formed by a round-trip line folded back at a fold portion 28, having a way forward and a way back short-circuited at a bridge 29. The second antenna element 22 is formed by a same element as the second antenna element 12a (each portion is given an updated reference numeral, though) to which the bridge 29 is added and from which the branch element 22a branches off.
The first feed portion 23, the first short-circuit portion 24, the second feed portion 25 and the second short-circuit portion 26 are in a same positional relationship as explained with respect to the first feed portion 13, the first short-circuit portion 14, the second feed portion 15 and the second short-circuit portion 16 of the antenna device 10a as shown in
In order to improve isolation between the first antenna element 21 and the second antenna element 22, the antenna device 20 as configured above has the first and second features which are same as the antenna device 10 or 10a of the first embodiment has.
As the open end 27 and the fold portion 28 where relatively high voltages are distributed are directed to go away from each other, a voltage-coupling between the first antenna element 21 and the second antenna element 22 may be suppressed, and isolation between the first antenna element 21 and the second antenna element 22 may be improved.
The antenna device 20 has the branch element 22a branch off for being multi-resonant and adds the bridge 29 for improving impedance matching. Meanwhile, having the features of the configuration in common with the antenna device 10a, the antenna device 20 may produce a same effect as the antenna device 10a does.
An effect of the first feature of the antenna device 20 has been estimated by simulation, and a result of the simulation will be explained with reference to
For the second embodiment, frequency ranges assigned to, e.g., mobile phones or Bluetooth are of interest and other frequency ranges are omitted from the horizontal axis in
In
As shown in
If the isolation is required to be no greater than −20 dB in
An effect of the second feature of the antenna device 20 has been estimated by simulation, and a result of the simulation will be explained with reference to
Each of portions shown in
Each of portions shown in
In
In
In
If the isolation is required to be no greater than −20 dB in
Meanwhile, the antenna device 20 (the diamond-shaped plots) having the first short-circuit portion in the range between the first feed portion 23 and the second feed portion 25 and having the open end 27 directed to go away from the second antenna element 22 meets the above requirement in most of the frequency bands shown in
In the above description, the square plots shown in
Thus, the isolation characteristic of the antenna device 20 has been estimated by simulation given the location of the first feed portion 23 (the distance from an end of the upper side of the PCB 1 farther from the second antenna element 22, i.e., the left end) as a variable parameter.
As shown in
That is, the antenna device 20 may meet the above required value of the isolation by setting the distance between the first feed portion 23 and the left end of the upper side of the PCB 1 to be no less than one-eighth wavelength and no greater than one-sixth wavelength of the resonant frequency of the first antenna element 21, and by having the first antenna element 21 directed from the first feed portion 23 to the left end of the upper side of the PCB 1.
The antenna device 20 of the second embodiment may be modified in a same way as shown in
According to the second embodiment of the present invention described above, the antenna device having plural antenna elements may be configured to select the positional relationship of the feed portions and the short-circuit portions and to select the positional relationship between the antenna elements associated with the high-and-low voltage or current distribution for improving the isolation between the antenna elements, in a case where the antenna elements are modified for multiple resonance or impedance matching.
A third embodiment of the present invention will be described with reference to
The antenna device 30 is formed by the antenna device 20 of the second embodiment and a third antenna element 33 added to the antenna device 20. Thus, each portion of the antenna device 30 except for the antenna element 33 is a same as the corresponding one of the antenna device 20 given the same reference numeral as shown in
The third antenna element 33 branches off from the second antenna element 22 near the second feed portion 25, and reaches an open end. The third antenna element 33 is arranged farther to the PCB 1 than the portion of the second antenna element 22 connected to the second short-circuit portion 26 is. In
For the third embodiment, the frequency ranges assigned to, e.g., mobile phones or Bluetooth are of interest as for the second embodiment. As to a resonant frequency of each of the antenna elements, it has been assumed, e.g., that the first antenna element 21 is given a frequency in a 2.4 gigahertz (GHz) band (Bluetooth), the second antenna element 22 in a 800 MHz band (mobile phones), the branch element 22a in a 1.7 GHz band (3G mobile phones), and the third antenna element 33 in a 2.1 GHz band (3G mobile phones).
In
The curves on the left and right sides of
As the VSWR of the dashed curve around 1.8 GHz values no less than 5 in the 2.1 GHz band, the antenna device 20 of the second embodiment is not suitable to be used in the 2.1 GHz band. Meanwhile, as the VSWR of the solid curve around 1.9 GHz values almost no greater than 3 in the 2.1 GHz band, the antenna device 30 is suitable to be used in the 2.1 GHz band. Development of multiple resonance by adding the third antenna element 33 to the antenna device 20 of the second embodiment has produced the improvement described above.
In
As shown in
As, in the configuration of the antenna device 30, the third antenna element 33 is located farther to the PCB 1 than the portion of the second antenna element 22 connected to the second short-circuit portion 26 is, image currents produced after the third antenna element 33 is excited are distributed rather on the second antenna element 22 than on the ground circuit of the PCB 1. As a result, influence of the image currents on the first antenna element 21 through the ground circuit of the PCB 1 and the first feed portion 23 may be suppressed.
In the configuration of the above modification of the antenna device 30 though, as the third antenna element 33 is located closer to the PCB 1 than the portion of the second antenna element 22 connected to the second short-circuit portion 26 is, the image currents produced after the third antenna element 33 is excited are distributed rather on the ground circuit of the PCB 1 than on the second antenna element 22. As a result, the image currents may easily affect the first antenna element 21 through the ground circuit of the PCB 1 and the first feed portion 23, and may cause the isolation characteristic to be inferior to the isolation characteristic of the antenna device 30.
As another example of developing multiple resonance by a configuration other than the antenna device 30, a parasitic element may be added to the antenna device 20 of the second embodiment. In that case, a configuration may be generally considered where a parasitic element having one end grounded is arranged near the second antenna element 25 for convenience of implementation. In the above configuration, however, image currents produced after the parasitic element is excited are distributed on the ground circuit of the PCB 1, and may cause the isolation characteristic to be inferior to the isolation characteristic of the antenna device 30, too.
In the configuration of the antenna device 30 shown in
Secondly, shorten a portion of the second antenna element 22 including the fold portion 28, where both the way forward and the way back are turned, as much as possible. If the above portion is long, lines before and behind the turn of both the way forward and the way back are coupled to each other, thus causing a condition similar to loading a lumped constant element.
Then, a frequency of third harmonics of the 800 MHz band may fall below a theoretical value, and in a case where, e.g., the first antenna element 21 is located close, the above third harmonics may interfere with the first antenna element 21. In order to avoid such interference, it is desirable to shorten the portion where both the way forward and the way back are turned as much as possible so as keep the frequency of the third harmonics from falling.
As shown in
The first antenna element 21 is formed directed away from the second antenna element 22 near the upper side of the PCB 1, while the open end 27 may be located near a left end of the upper side of the PCB 1. In a same way as described with respect to the second embodiment, the antenna device 30 may improve the isolation by setting the distance between the first feed portion 23 and the left end of the upper side of the PCB 1 to be no less than one-eighth wavelength and no greater than one-sixth wavelength of the resonant frequency of the first antenna element 21, and by having the first antenna element 21 directed from the first feed portion 23 to the left end of the upper side of the PCB 1.
In a same way as shown in
According to the third embodiment of the present invention described above, multiple resonance of the antenna device may further be developed, and the isolation between the antenna elements may be improved.
In the above description of the embodiments, the shapes, the configurations and the connections of the antenna devices, the frequency values, etc. are considered as exemplary only, and thus may be variously modified within the scope of the present invention.
The particular hardware or software implementation of the present invention may be varied while still remaining within the scope of the present invention. It is therefore to be understood that within the scope of the appended claims and their equivalents, the invention may be practiced otherwise than as specifically described herein.
Number | Date | Country | Kind |
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2007-176503 | Jul 2007 | JP | national |