This application is based upon and claims the benefit of priority of the prior Japanese Patent Application No. 2013-073403, filed on Mar. 29, 2013, the entire contents of which are incorporated herein by reference.
1. Field of the Invention
The disclosed embodiment relates to an antenna device and a radar device.
2. Description of the Related Art
Conventionally, an antenna device in which a plurality of microstrip antennas each configured with a set of radiating elements arranged in series on a feedline is arranged in parallel on a surface of a dielectric substrate is known (e.g., Japanese Patent Application Laid-open No. 8-167812).
Such antenna device is installed, for example, in an onboard radar device for a vehicle and used, for example, for a vehicle following function in which a vehicle running ahead of, and on the same lane as, the own vehicle is detected as a target and the own vehicle follows the vehicle running ahead.
Specifically, the antenna device disclosed in Japanese Patent Application Laid-open No. 8-167812 is equipped with an insulation plate layered on a portion of the dielectric substrate on which the feedline is formed so as to insulate the feedline from the space. Thereby, unwanted radiation of radio wave from the feedline and a feeder circuit including a radiating element is restrained.
However, there is still a room for improvement in the prior art described above to prevent a radio wave interference occurring between neighboring microstrip antennas.
For example, it is known that the radio wave propagates not only in a space but also in the dielectric substrate, an adhesive sheet for bonding the dielectric substrate to a housing which acts as a waveguide, or the like. Therefore, the prior art described above is insufficient for restraining such propagation and preventing radio wave interference.
The radio wave interference can be prevented by lengthening the distance between the neighboring microstrip antennas. However, the lengthening is not preferable because the device may fail to satisfy the required level of performance, and the space for arrangement become large.
It is an object of the present invention to at least partially solve the problems in the conventional technology.
An antenna device according to an aspect of an embodiment includes a dielectric substrate, a housing, and an interference prevention unit. On the top surface side of the dielectric substrate, a plurality of antennas is formed, and on the bottom surface side, a ground is formed, each as a conductive thin film pattern, respectively. The housing is formed of a conductive material, and formed to have a shape configured to function as a waveguide, and the top surface side of the housing is bonded to the bottom surface side of the dielectric substrate. The interference prevention unit is formed between the neighboring antennas to include at least a groove provided on the top surface side of the housing and a slit provided on the ground in the portion corresponding to the groove.
A more complete appreciation of the invention and many of the attendant advantages thereof will be readily obtained as the same becomes better understood by reference to the following detailed description when considered in connection with the accompanying drawings, wherein:
An embodiment of an antenna device and a radar device disclosed herein will be described below in detail referring to the attached drawings. The present invention is not limited to the embodiment described below.
An outline of a radio wave interference prevention technique according to the embodiment will be described below using
The antenna is considered to be a microstrip antenna in the following description.
First, an outline of the radio wave interference prevention technique according to the embodiment is described using
As illustrated in FIG. IA, the antenna device 10′ according to the prior art includes a dielectric substrate 11. The dielectric substrate 11 is formed using an insulative resin material or the like. The dielectric substrate 11 is an example of a dielectric means.
Further, an antenna 12 is provided on the top surface side of the dielectric substrate 11. Two antennas, that is, a first antenna 12-1 and a second antenna 12-2 are provided in parallel as antennas 12. Further, a ground 13 is provided in the bottom surface side of the dielectric substrate 11.
Each of the antenna 12 and the ground 13 is formed as a thin film pattern of a conductive metal. The thin film pattern is formed by forming a thin film of copper or the like on the entire surface of the dielectric substrate 11 using a technique such as sputtering and vacuum evaporation followed by patterning of the thin film using photo etching or the like.
Further, the antenna device 10′ includes a housing 15 which acts as a waveguide. The housing 15 is an example of a waveguide means. The housing 15 is a block of conductive material, for example, a rectangular parallelepiped block formed by the aluminum die-casting and has a hollow portion 16.
As illustrated in
In each drawing used for the description, a rough schematic cross sectional view, as illustrated in
It is assumed that, for example, the radio wave is radiated from the first antenna 12-1 as illustrated in
Therefore, the radio wave interference is likely to occur between the neighboring antennas 12, which causes a distortion in the amplitude or the phase of the radio wave. In other words, the isolation between the neighboring antennas 12 is deteriorated.
In the radio wave interference prevention technique according to the embodiment, an interference prevention unit which is a mechanism for preventing the radio wave interference is provided between the neighboring antennas 12. The interference prevention unit is an example of an interference prevention means.
Specifically, in the radio wave interference prevention technique according to the embodiment, an interference prevention unit, for example, a hollow-structured groove (hollow groove 17), is provided between the neighboring antennas 12, as illustrated in
In other words, the antenna device 10 to which the radio wave interference prevention technique according to the embodiment is applied includes the hollow groove 17 formed so as to communicate slits provided on the ground 13 and the adhesive sheet 14, respectively, and a groove formed on the housing 15.
By providing the hollow groove 17 to the antenna device 10, the radio wave propagating via the space, the dielectric substrate 11, and the adhesive sheet 14 can be cut off at the edge of the hollow groove 17 (see the arrow 104 in the drawing). Detail of the structure and the effect of the hollow groove 17 will specifically be described using
As described above, by using the radio wave interference prevention technique according to the embodiment, the radio wave interference occurring between the neighboring antennas 12 can be prevented. Thereby, the isolation of the antenna 12 can be kept in preferable condition without causing a distortion in the amplitude or the phase of the radio wave.
Now, the exemplary structure of the first embodiment in which the hollow groove 17 illustrated in
Further in the description below, for a component constituted of a plurality of elements, only a portion of the plurality of elements may be appended with numerals, and the numerals for the other portions of the plurality of elements may be omitted. In such case, a portion appended with numerals and the other portions without numerals have a similar configuration.
Further in the description below, the description may be omitted or shortened for a component of which description duplicates with the description on the antenna device 10′ illustrated in
As illustrated in
As illustrated in
In the antenna 12, a linear array is formed by a linearly extending feedline 12a and a plurality of radiating elements 12b which is branched from the feedline 12a and excited at a same phase as that of the feedline 12a.
The feedline 12a is a microstrip line of which end is connected to a converter 12d via a feeding terminal 12e. A terminal end element 12c for restraining reflection is formed in the other end of the feedline 12a. Further, the radiating element 12b has a shape of an approximately squared shape which extends in the direction which intersects with the feedline 12a at a given angle.
The converter 12d is provided in the portion corresponding to the hollow portion 16 as described above, and mutually converts the transmission powers of the housing 15 and the feeding terminal 12e, via an exciter element 18 which will be described later.
The antenna device 10 further includes the hollow groove 17 as the interference prevention unit. The hollow groove 17 is linearly provided in an approximately middle location between the antennas 12, and to be approximately parallel to the antenna 12. In the description below, it is assumed that the hollow groove 17 is formed to have width W as illustrated in
Further, the antenna device 10 is installed in, for example, a radar device 100. Here, the antenna device 10 is assumed to be installed in the radar device 100, and its internal structure will be described.
Further, the exciter element 18 is provided on the bottom surface of the dielectric substrate 11 in a portion corresponding to the hollow portion 16. The exciter element 18 receives a radio wave from the hollow portion 16 and transmits to the antenna 12 (the first antenna 12-1 in the drawing).
Further, the bottom surface side of the housing 15 is bonded to a integrated circuit substrate 21. The integrated circuit substrate 21 includes a monolithic microwave integrated circuit, so-called a MMIC (Monolithic Microwave Integrated Circuit) 22, which performs signal processing such as oscillation, amplification, modulation, and frequency conversion of the microwave signal.
In this manner, the antenna 12 and the MMIC 22 are connected by waveguide connection via the housing 15. The integrated circuit substrate 21 is contained in a casing 30 of which top portion is covered by a covering member, that is, a radome 40, and in this manner, the radar device 100 is constituted.
Further, as illustrated in
Since the housing 15 is formed by, for example, aluminum die-casting, an R shape is often formed on the edge of the bottom portion of the groove 17c as illustrated in
Further, a depth D of the groove 17c may preferably have a dimension corresponding to about a quarter wavelength of the guide wavelength of the radio wave of which frequency is used in the antenna device 10. Therefore, the overall depth of the hollow groove 17 is D±n, that is, the depth D having a dimension of about a quarter wavelength added or subtracted with the allowable difference n including thicknesses and geometrical tolerances of the ground 13 and the adhesive sheet 14.
The effect of forming the hollow groove 17 in the manner described above will be described using
As illustrated in
That is, the radio wave propagating the space from the first antenna 12-1 toward the second antenna 12-2 can be cut off at the end portion of the hollow groove 17. Thereby, the radio wave interference between the neighboring antennas 12 is restrained so that the isolation between the antennas 12 can be improved.
Now,
Further, for the convenience of explanation in
As illustrated in
Then the incident wave propagates into the hollow groove 17. An incident wave which propagates toward the bottom portion of the hollow groove 17 reflects at the bottom portion. If the depth D of the groove 17c (see
When the reflected wave having the phase difference of n progresses the same depth D in the returning path and reflects, an additional phase difference of π is produced. Therefore, as illustrated in
Contrary, the phase difference between the incident wave which enters from section a into section b and the reflected wave which propagates toward section b after the reflection at the bottom portion of the hollow groove 17 is n as illustrated in
That is, the width of the slit 17b provided on the adhesive sheet 14 (see
Consequently, in section b, the incident wave and the reflected wave have phases opposite to, and thereby canceling, each other, by which the radio wave from the first antenna 12-1 does not propagate toward the second antenna 12-2.
In this manner, the radio wave which propagates in the adhesive sheet 14 from the first antenna 12-1 toward the second antenna 12-2 can be cut off by the hollow groove 17. That is, the radio wave interference between the neighboring antennas 12 is restrained and the isolation between the antennas 12 can be improved.
The radio wave propagating in the dielectric substrate 11 can be cut off by the similar principle, although the description will be omitted. Therefore, as for the dielectric substrate 11, the propagating radio wave can be cut off to restrain the radio wave interference by providing the hollow groove 17, and the isolation between the antennas 12 can be improved.
The relation between the depth D and the isolation between the antennas 12, which is obtained by actually simulating the first embodiment, is illustrated in
As illustrated in
Further, as illustrated in
Now, an exemplary variation of the hollow groove 17 will be described using
As illustrated in
Although the thickness of the adhesive sheet 14 illustrated in
Further, the adhesive sheet 14 need not be processed, which contributes to improving efficiency of the manufacturing process.
Further, as illustrated in
The width W and the length L of the slit 17S should have, at least, the relation of W<L. Further, as illustrated in
As described above, by providing the divided slit 17S on the ground 13, the radiant quantity of the radio wave radiated from the slit 17S can be increased. That is, the radio wave interference between the antennas 12 can be restrained, which contributes to improving the isolation between the antennas 12.
As described above, in the first embodiment, the antenna device including the dielectric substrate, the housing, and the interference prevention unit is constituted. On the top side of the dielectric substrate, a plurality of antennas is formed, and on the bottom side, the ground is formed, each as a conductive thin film pattern.
The housing is formed of a conductive material and in a shape which acts as a waveguide. The top side of the housing is bonded to the bottom side of the dielectric substrate. The interference prevention unit is provided between the neighboring antennas.
Further, the interference prevention unit is formed to include, at least, a groove provided on the top surface side of the housing and a slit provided on the ground in the portion corresponding to the groove.
Therefore, by using the antenna device and the radar device using the antenna device according to the first embodiment, the radio wave interference occurring between the neighboring antennas can be prevented.
In the first embodiment described above, the description is made for the case in which the hollow groove is provided between the neighboring antennas as an interference prevention unit, though an opening may additionally be provided on the dielectric substrate between the antennas. Such case will be described as the second embodiment using
In
As illustrated in
As in the manner described above, by providing a communication from the housing 15 through the dielectric substrate 11 and providing the groove 17′ opened on the dielectric substrate 11, the radio wave propagating in the dielectric substrate 11 and the adhesive sheet 14 can efficiently be radiated from the opening, thereby contributing to the prevention of the radio wave interference.
Further, as illustrated in
In this manner, the electric line of force from the antenna 12 can surely be introduced in the direction toward the ground 13 on the dielectric substrate 11, thereby also contributing to the prevention of the radio wave interference. A plurality of such through holes H is preferably provided along the extending direction of the hollow groove 17 (i.e., the X-axis direction in the drawing). When the hole diameter of the through hole H is small, the through hole H introduces the electric line of force from the antenna 12 in the direction toward the ground 13 on the dielectric substrate 11. When the hole diameter of the through hole H is large, the through hole H introduces the electric line of force from the antenna 12 in the direction toward the ground 13 on the dielectric substrate 11, and allows unnecessary radio wave propagating in the dielectric substrate 11 and the adhesive sheet 14 to radiate outside from the through hole H. In the case when a plurality of through holes H is provided in the X-axis direction, each distance between through holes H may preferably be the distance corresponding to a quarter wavelength, or less, of the guide wavelength of the radio wave having a frequency used in the antenna device 10.
Further, as illustrated in
In this manner, when the hole diameter of the through hole H is small, the through hole H can introduce the electric line of force from the first antenna 12-1 and the second antenna 12-2 in the direction toward the ground 13 on the dielectric substrate 11, respectively. When the hole diameter of the through hole H is large, the through hole H allows the radio wave propagating from the first antenna 12-1 and the radio wave propagating from the second antenna 12-2 to radiate independently from the through hole H, which also restrains the radio wave interference and can thereby improve the isolation between the antennas 12.
That is, also by using the antenna device and the radar device using the antenna device according to the second embodiment, the radio wave interference occurring between the neighboring antennas can be prevented.
In the first embodiment described above, description is made for the case in which the slit is provided on the ground divided by a given length in the longitudinal axial direction of the antenna device (see
As illustrated in
In this manner, the polarization direction of the radio wave radiated from the slot 17S′ can be shifted. The arrow 1001 illustrated in
By providing the slot 17S′ with the inclination of 45 degrees as illustrated in
The radiating element 12b of the antenna 12 is provided so as to extend in the direction which intersects with the feedline 12a at the inclination angle of 45 degrees, by which a 45 degrees of polarization is obtained. In this case, as illustrated in
That is, as illustrated in
Description is made above for the example in which the slot 17S′ has an inclination of 45 degrees, though it is not limited to the case. Any case may be carried out as long as an inclination can be provided to the slot 17S′ so as to give the angle difference of 90 degrees relative to the corresponding polarization direction of the antenna 12, that is, the inclination provided to the radiating element 12b.
In this manner, also by using the antenna device and the radar device using the antenna device according to the third embodiment, the radio wave interference occurring between the neighboring antennas can be prevented.
For each of the embodiments described above, description is made, as an example, for the case in which the antenna is a microstrip antenna, though the antenna is not limited to the microstrip antenna.
For example, application may be made to a so-called triplate type planer antenna or the like in which a dielectric sheet such as a foam material is attached on each of the top and the bottom of a film substrate that is etched with a copper foil pattern, and the dielectric sheets are further attached with parallel plates on both the top and the bottom sides thereof.
Further, for each of the embodiments described above, description is made, as an example, for the case in which the antenna is in a form of a linear array, in which the linear arrays are arranged in parallel so as to be approximately parallel, though it is not limited to the case. That is, if a plurality of antennas neighboring each other is provided, each of the pattern shapes of the antennas is not a problem.
Further, for each of the embodiments described above, description is made, as an example, for the case in which the binder is an adhesive sheet, though it is not limited to the case. For example, an adhesive such as an epoxy resin based adhesive having a high insulating property may be used.
According to one aspect of the embodiment, the radio wave interference occurring between neighboring antennas can be prevented.
Additional advantages and modifications will readily occur to those skilled in the art. Therefore, the invention in its broader aspects is not limited to the specific details and representative embodiments shown and described herein. Accordingly, various modifications may be made without departing from the spirit or scope of the general inventive concept as defined by the appended claims and their equivalents.
Number | Date | Country | Kind |
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2013-073403 | Mar 2013 | JP | national |