1. Field of the Invention
This invention relates to an ultra wideband antenna and an ultrahigh frequency circuit module that can be applied to an ultra-wideband wireless system or the like to enable high speed transmission.
2. Description of the Related Art
In recent years, close range wireless interfaces such as wireless LANs and Bluetooth (trademark) have become widely used, but ultra-wideband wireless systems (UWB) have been receiving attention as the next generation of systems to enable even higher speed transmission. Specification investigations are currently progressing in various countries, but it is recognized that the usage frequency for these UWB systems in the US is 3.1-10.6 GHz with a comparatively large output. This UWB system is capable of high speed wireless transmission at 100 Mbps or above due to use of high frequencies in an extremely wide band, but it is not easy to implement an antenna for transmission of this type of wideband signal.
The major factor hampering wideband characteristics is widely known to be that input impedance matching of the antenna cannot be achieved. There are two causes for this, the first that there is large variation in antenna input impedance due to frequency, and the second is that the antenna input impedance and the external impedance are different.
The present invention solves the above described problems, and provides an ultra-wideband antenna and an ultrahigh frequency circuit module to achieve an extremely wide band.
An ultra-wideband antenna of the present invention is provided with a dielectric substrate, a plurality of antenna conductors formed on one surface of the dielectric substrate that are pseudo self complementary on the surface, and a plurality of feed conductors symmetrical with respect to a symmetrical surface of the antenna conductors, wherein a gap for a wavelength of 1/10 or less that of the wavelength of a usage frequency in a vacuum is provided at a center of rotational symmetry between the plurality of antenna conductors.
It is possible for the plurality of feed conductors to be provided on a surface opposite to the surface provided with the plurality of antenna conductors, and to provide a plurality of via holes passing through the dielectric substrate symmetrically with respect to a symmetrical surface of the plurality of antenna conductors to connect the plurality of feed conductors to the plurality of antenna conductors.
It is also possible to further provide a second dielectric substrate on the antenna conductors, arranged so that the antenna conductors are sandwiched by a plurality of dielectric substrates.
It is also possible to have a structure where widths of the feed conductors are different at a conductor body side and at an opposite end, and width of the feed conductors changes monotonically between the two ends.
In the event that the output impedance of an electronic circuit connected to the feed conductors is lower than the input impedance of the antenna, it is preferable for the width of the feed conductors to be narrow at a side connecting to the antenna conductors and wide at a side connecting to the electronic circuit.
In the event that the output impedance of an electronic circuit connected to the feed conductors is higher than the input impedance of the antenna, it is preferable for the width of the feed conductors to be wide at a side connecting to the antenna conductors and narrow at a side connecting to the electronic circuit.
In order to obtain impedance matching, it is necessary for a median between the impedance of an electronic circuit connected to the feed conductors and the impedance of the antenna to be realized at a midpoint of the feed conductors.
It is also possible for the plurality of feed conductors to include first sections provided on the same surface as other feed conductors, and second sections provided on surfaces opposite to the first sections, and via holes to be provided passing through the dielectric substrate to connect the first sections to the second sections, wherein the second sections and the other feed conductors constitute lecher wires sandwiching the dielectric substrate.
It is also possible to provide a microstrip connection line including ground conductor provided on a surface opposite to the surface provided on the feed conductors, and for the feed conductors to be connected to the microstrip connection line.
The widths of lecher wires and microstrip connection lines are selected so that an impedance R1 of lecher wires constituted by the feed conductors matches with an impedance R2 of the microstrip connection lines in odd mode at a desired value or less where they connect.
More specifically, line widths are selected so that at sections where lecher wires and microstrip connection lines connect, the lecher wire impedance and the odd mode impedance cause reflection to be as small as possible at a desired bandwidth. As an example of this method, there is matching design theory using a lambda/4 transformer. If this is done, at joints of the lines, it is possible to connect with no almost no reflection loss in the desired band.
A wideband high frequency circuit module of the present invention is made up of only balanced circuits, and is provided with a ultra-wideband antenna, a semiconductor integrated circuit and a connection line. The antenna is provided with a dielectric substrate, a plurality of antenna conductors formed on one surface of the dielectric substrate that are pseudo self complementary on the surface, and a plurality of feed conductors symmetrical with respect to symmetrical surfaces of the antenna conductors, wherein a gap for a wavelength of 1/10 or less that of the wavelength of a usage frequency in a vacuum is provided at a center of rotational symmetry between the plurality of antenna conductors. The semiconductor integrated circuit, has an output impedance of greater than or equal to 80 ohms and less than or equal to 300 ohms, for outputting a differential signal. The connection line connects the antenna and the semiconductor integrated circuit.
The present invention provides a method for implementing an extremely wideband antenna. In order to achieve antenna input impedance matching over a wide band, with the present invention set impedance characteristics that are not dependent on frequency are implemented with a pseudo self complementary antenna structure.
That constant impedance is normally about 200 ohms, and this is away from the vicinity of 50 ohms, which is a normal value for external impedance. The present invention provides a pattern for matching such significantly different impedances. This way of achieving impedance matching is being widely researched with unbalanced circuits, but in the antenna structure of the present invention, electrical supply lines are a necessity for balanced circuits, and there is a need for an appropriate matching method.
With respect to excitation of an antenna of the present invention, when forming a wireless module because it is necessary to perform excitation using a balanced signal it is necessary to supply balanced signals from outside. It is possible to convert between balanced signals and unbalanced signals using a balun (balanced to unbalanced converter), but in the case of handling signals of a wide band such as UWB, for example, the band of 3.1-10.6 GHz that is permitted u the US, it is necessary to make a balun that covers the wide band, which means that manufacture is extremely difficult, and cost is extremely high. With the present invention, there is also provided a structure for an ultra-wideband wireless module formed completely of balanced circuits, without the need for such a high cost balun.
According to the present invention, it is possible to realize an antenna with little reflection loss over an extremely wideband range, and a high frequency circuit (module) including the antenna.
a) is a plan view of an antenna module relating to embodiment 1 of the invention.
b) is an enlarged view of a central part of an antenna.
c) is another enlarged view of central part of the antenna.
a) and 12(b) are a plan view of an antenna module relating to embodiment 3 of the invention.
An antenna relating to embodiment 1 of the invention will now be described with reference to the drawings.
b) is an expanded drawing of a central part of the antenna.
The antenna of the first embodiment of the invention is obtained by any combination of
The antenna conductors 1, 2 are provided on one surface on the dielectric substrate 11. At central parts of the antenna conductors 1, 2, parts of the conductors that are 1/10th or less the wavelength of the usage frequency in a vacuum are removed, and the antenna conductors 1, 2 are arranged a specified distance apart. With an ideal self-complementary structure, the distance is infinitely small, but because the antenna conductors 1, 2 will fail in their function if they are short circuited, in actual manufacture there is a need for a permissible distance. If the distance is 1/10th of a wavelength or less, an electric field is almost in an ideal state and a large difference does not arise, which means that by providing a distance of 1/10th of a wavelength or less, the characteristics are not affected, and it is possible to acquire a manufacturing margin (Preferably 1/30th of a wavelength or less. If it is any smaller, the difference between an ideal state can be made sufficiently small.).
The antenna conductors 1, 2 are left right symmetrical about the axis of symmetry AS, and if they are turned 180 degrees about the point of symmetry PS the antenna conductors overlap themselves, while if they are rotated 90 degrees they overlap with the section with no pattern except for the central distant portion, giving a self complementary structure. Since the above described distance L exists, it cannot be said that the antenna of
The dimensions etc. of the antenna of
As shown in
Results of evaluation using electromagnetic field simulation as to whether or not antenna impedance etc. is changed by changing the distance between the antenna conductors 1, 2 are shown in
The wavelength of 5 GHz in air is 6 cm, and a distance of 6 mm is 1/10th of a wavelength, which means that when a pattern at the central part of the antenna is cut within a length under 1/10th of a wavelength or less, it is considered that a fixed impedance characteristic is ensured. In order to further ensure a fixed impedance, it is preferable to have a distance of 2 mm, that is 1/30th of a wavelength, or less.
As an example, an antenna having the structure described below was test produced and the characteristics measured.
As a dielectric substrate, a substrate having a dielectric constant of 3.6 and a dielectric thickness of 200 μm was used. The length of two edges interposed in right angles of antenna conductors 1, 2 shaped as right-angled isosceles triangles is 28 mm. A distance between the antenna conductors 1, 2 is 0.25 mm, and feed lines having a width of 0.25 mm are extracted from apexes of the right angles of the antenna conductors 1, 2 symmetrically about the line of symmetry of the antenna conductors 1, 2. A distance between the feed conductors 3, 4 is 0.25 mm. The feed conductors 3, 4 are taken out as far as outside of a square formed by ends of two edges interposed between the right angles of the antenna conductors 1, 2.
This reflected power amount represents power from an external circuit that is reflected by the antenna and not conveyed to the antenna, and it is common practice to use this value in a region of −10 dB or less, as a criterion of bandwidth. According to
As should be clear from the above description, according to embodiment 1 of the present invention, it is possible to realize an antenna with little reflection loss over an extremely wideband range.
With embodiment 1 of the present invention, a dielectric substrate is provided on one surface of the antenna conductor, but it is also possible to provide a dielectric substrate on both surfaces. Examples of embodiment 2 of the present invention are shown in
The structure of embodiment of the invention is the same as the first embodiment with respect to the antenna conductors 1, 2, but a second dielectric substrate 91 is also provided with the dielectric substrates being arranged on both surfaces of the antenna conductors 1, 2. In order to connect to external circuits, the feed conductors 3, 4 are provided on a rear surface of the dielectric substrate 11, and are connected to the antenna conductors 1, 2 by means of via-holes 12 (it is also possible to provide the feed conductors 3, 4 on the main (or front) surface of the second dielectric substrate 91).
With the structure of embodiment 2 of the invention, since the dielectric bodies 11, 91 are on both surfaces of the antenna conductors 1, 2, the effective relative dielectric constant is even higher than with the structure of embodiment 1 of the invention, and as well as the value at the time of constant impedance becoming lower, it is made possible to obtain the same electrical characteristics even with a shorter physical length as the electrical length is shorter, enabling miniaturization of the antenna. Since the antenna impedance of this invention is comparatively high, a lower impedance is more effective to enable matching over a wide band with low loss when connecting to a balanced circuit of 50 ohms (the impedance between lines is 100 ohms because it is double due to being interposed by ground) that is often used with high frequencies.
Similarly, with respect to the shape and dimensions of the antenna conductors,
According to
It is possible to endow the feed conductors with a impedance conversion function. Examples of embodiment 3 of the present invention are shown in
In
In embodiment 3 of the invention, if the width of the end 5 of the feed conductor 3 is compared with the width of the other end 38 (the end at the antenna conductor 2 side) the width becomes monotonically larger moving from the end 38 to the end 5. The same applies to the width of the end 6 of the feed conductor 4 and the width of the other end 37 (antenna conductor 1 end). With the example of
In
In embodiment 3 of the invention, the structure of the antenna conductors 1, 2 and the dielectric substrate 11 is the same as for embodiment 1 and embodiment 2 of the invention. The width of the feed conductors 3, 4 is narrow at parts 37, 38 connected to the antenna conductors 1, 2, and wide at sides (at the ends 5, 6) fed from outside. The width of the feed conductors 3, 4 may also be constant, or vary in a monotonic manner, and the two feed conductors 3, 4 are symmetrical with respect to the plane of symmetry of the antenna conductors 1, 2. Since the width of the feed conductors 3, 4 is as described above, even when output impedance of an LSI connected to the feed conductors 3, 4 is lower than the antenna input impedance, external signal source impedance is matched to the antenna.
When the LSI output impedance is higher than antenna input impedance, opposite to the situation described above, the width of the feed conductors 3, 4 is such that it is wide at parts 37, 38 connected to the antenna, and becomes narrow at sides 5, 6 fed from outside. The circuit line widths may also be constant, or vary in a monotonic manner, and the two feed conductors 3, 4 are symmetrical with respect to the plane of symmetry of the antenna conductors 1, 2.
As shown in
In order to demonstrate the effects of the structure of embodiment 3 of the invention, an impedance converting effect as described in the following is shown using electromagnetic field simulation. Here, impedance of circuit lines when obtaining impedance matching is a value between the impedance of the two sides, which means that if impedance can not be realized at a value between the impedance of the two sides it is not possible to achieve matching.
The shape of the lines at this time is such that an antenna conductor side width is 0.1 mm, an external feed point side is 0.25 mm, and a gap is 0.15 mm. As well as antenna side reflection S11 and feed side refection S22, reflection spanning the wide band of the UWB band currently permitted in the US (3.1-10.6 GHz) has almost no reflection loss at less than −19 dB, and it will be understood that favorable matching is achieved.
As should be clear from the above description, according to the antenna relating to embodiment 3 of the present invention, it is possible to realize an antenna with little reflection loss over an extremely wideband range and which can achieve matching of impedance between an external feed section and the antenna.
Embodiment 4 of the present invention is shown in
As shown in
In embodiment 4 of the invention, the antenna section is the same as the antenna conductors of embodiments 1 and 2 of the invention, and the structure of the dielectric substrate is the same, but the feed conductors are as shown in
According to embodiment 4 of the invention, since some of the feed lines constitute lecher wires sandwiching the dielectric body, it is possible to achieve a lower impedance than with embodiment 3 of the invention. As a result, even if the antenna side impedance is the same, it becomes possible to achieve matching with a lower external impedance.
According to embodiment 4 of the present invention, it is possible to realize an antenna with little reflection loss over an extremely wideband range and which can also achieve impedance matching to a comparatively low impedance external feed section.
In
With embodiment 5 of the invention, the feed conductors 61 and 62 are connected to microstrip lines 64 and 65 having ground surfaces on opposite surfaces. The widths of the microstrip connection lines are selected to be of such a width that an impedance R1 of lecher wires constituted by the feed conductors matches at a point where they connect and an impedance R2 of the microstrip connection lines 64, 65 in odd mode.
With the structure of embodiment 5 of the invention, there is connection from the lecher wires 61 and 62 to the microstrip connection lines 64 and 65. With a high frequency circuit, in order to make the ground voltage constant it is common to provide an electrode that is grounded. In the vicinity of an antenna section having this structure, it is better if the ground electrode is far away, but there are many cases where it is better to have the ground electrode at a section connected from the feed conductors to the external circuit.
Embodiment 5 of the invention makes it possible to convert to a balanced circuit containing a ground electrode at a midpoint of a feed line. The microstrip connection lines have voltage and current out of phase by 180 degrees between lines at the time of odd mode, and the same phase as those of the lecher wires, which means if the line width is selected so that at connection sections between the lecher wires and the microstrip connection lines a difference between the impedance of the lecher wires and the odd mode impedance is small, it is possible to connect at a line join with almost no reflection loss. Here, the odd mode impedance is defined as the impedance with respect to ground, and so the odd mode impedance between lines of the microstrip connection lines is the result of adding the impedance from one line to ground to the impedance from ground to the other line. With a symmetrical circuit, the two impedances are equal, which means that the impedance between the lines becomes twice the odd mode impedance. Therefore, by selecting the line width and distance between lines so that the impedance of the lecher wires becomes twice the impedance of the microstrip odd mode impedance, it is possible to make impedances at line joins equal, and to have almost no reflection loss, and to have impedance conversion with no loss.
As will be clear from the above description, according to embodiment 5 of the invention, since it is possible to realize a simple antenna module that has low reflection loss and does not require a balun (balanced to unbalanced converter), a high performance, high yield, low cost module is possible.
The above-described embodiments relate to an antenna module. Embodiment 6 of the invention relates to a wireless module using the above described antenna module.
The semiconductor integrated circuit 71 has an output impedance in the range 80 to 300 ohms, and outputs a differential signal. At this time, output impedance is designed to the output impedance by adjusting gate width in the case of field effect transistors, or by adjusting emitter area in the case of bipolar transistors. The impedance of the antenna relating to this embodiment of the present invention changes from about 80-300 ohms depending on structural dimensions, but by selecting the output impedance of an-LSI that is close by, it is possible to more simply achieve impedance matching using the methods shown in embodiments 3-5 of the invention. It is also possible to have a balanced circuit such as a mixer between 73 and the LSI 71, instead of the balanced line circuit.
The wireless module circuit is constituted so that a differential signal is taken out from the LSI 71 having an output impedance of 80-300 ohms using two impedance matched lecher wires or a odd mode connection line circuit 74, and this signal is connected to the balanced circuit 72 so that the balanced output of a balanced circuit 72 such as a balanced mixer constituted by a balanced circuit is input to the antenna of embodiments 1-5 of the present invention using lecher wires or odd mode connection line circuits 75 that achieve impedance matching of the balanced outputs of a balanced circuit 72. The intermediate balanced circuit 72 is not absolutely necessary, and in the event that it is not provided, there is a direct connection from the LSI 71 to the antenna 73 using impedance matched lecher wires or odd mode connection line circuits 74.
At the balanced circuit 72 and the antenna 73, it is necessary to input signals that are 180 degrees different in phase from one another, but with a circuit constituted only by the balanced circuit as shown in
The present invention is not limited to the above-described embodiment, and various modifications are possible within the scope of the attached claims. These are also included within the spirit and scope of the present invention.
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