The present disclosure relates to a coaxial waveguide transducer and a method of forming the same.
Many band pass filters and duplexers used in a microwave band or a millimeter wave band are formed using waveguides. However, an electronic circuit cannot directly handle a high-frequency signal transmitted through the waveguide. Therefore, when the band pass filter and the duplexer are used, they are often connected to a coaxial waveguide transducer configured to perform transduction between a waveguide and a coaxial line. Examples of the coaxial waveguide transducer are disclosed in Non-Patent Literature 1 and 2.
In the coaxial waveguide transducer disclosed in Non-Patent Literature 1, a coaxial line and a waveguide are connected to each other in such a way that they are orthogonal to each other, and a short-circuiting plane is provided in the waveguide. Then, inside the waveguide, a signal is transmitted in a direction that is perpendicular to a signal transmission direction in the coaxial line and is opposite to the short-circuiting plane. A coaxial waveguide transducer having a structure similar to that disclosed in Non-Patent Literature 1 is disclosed in Non-Patent Literature 2 as well.
In recent years, the sizes of band pass filters and duplexers used in high-frequency bands have been reduced. In accordance therewith, it is required to reduce the size of the coaxial waveguide transducer as well. Further, the coaxial waveguide transducer needs to satisfy reflection characteristics indicating a reflection loss (return loss) in a desired band.
According to the coaxial waveguide transducer having the structure disclosed in Non-Patent Literature 1 and 2, when the distance between the coaxial line and the short-circuiting plane is made large, reflection characteristics can be satisfied in one band. However, when the distance between the coaxial line and the short-circuiting plane is made large, the size of the coaxial waveguide transducer increases.
Therefore, there is a problem that, with the coaxial waveguide transducer having the structure disclosed in Non-Patent Literature 1 and 2, it is unable to achieve both miniaturization and satisfaction of reflection characteristics.
The present disclosure aims to provide a coaxial waveguide transducer and a method of forming the same capable of solving the aforementioned problem and achieving both miniaturization and satisfaction of the reflection characteristics.
In one aspect, a coaxial waveguide transducer includes:
a waveguide having a substantially L shape formed of a first waveguide part and a second waveguide part arranged substantially orthogonal to each other, the waveguide having one end which is on the side of the first waveguide part to which a coaxial line is connected;
a stepwise step bend part formed in an outer corner part of an L-shaped bent part of the waveguide;
a first conductor and a second conductor arranged in respective inner side walls of the first waveguide part in such a way that they are extended in a direction in which a central conductor of the coaxial line is extended and are positioned on a plane the same as that where the central conductor is provided; and
a third conductor having one end connected to the central conductor and another end connected to one of the first conductor and the second conductor, the third conductor being arranged obliquely with respect to the direction in which the central conductor is extended.
In one aspect, a method of forming a coaxial waveguide transducer comprises:
providing a waveguide having a substantially L shape formed of a first waveguide part and a second waveguide part arranged substantially orthogonal to each other, the waveguide having one end which is on the side of the first waveguide part to which a coaxial line is connected;
forming a stepwise step bend part in an outer corner part of an L-shaped bent part of the waveguide;
arranging a first conductor and a second conductor in respective inner side walls of the waveguide in such a way that the first conductor and the second conductor are extended in the direction in which a central conductor of the coaxial line is extended and are positioned on a plane the same as that where the central conductor is provided; and
arranging a third conductor in such a way that one end is connected to the central conductor and another end is connected to one of the first conductor and the second conductor, and that the third conductor is extended obliquely with respect to the direction in which the central conductor is extended.
According to the aforementioned aspects, it is possible to provide a coaxial waveguide transducer and a method of forming the same capable of achieving both miniaturization and satisfaction of the reflection characteristics.
Hereinafter, with reference to the drawings, an embodiment of the present disclosure will be explained. Further, specific numerical values and the like stated in the following embodiments are merely examples for facilitating understanding of the present disclosure, and are not limited thereto.
As shown in
The waveguide 10 has one end (x-direction positive side) on the side of the first waveguide part 10A to which a coaxial line 20 is connected in series, through which a signal of a coaxial line system is input to the waveguide 10 or output from the waveguide 10. Note that a central conductor 21 of the coaxial line 20 has a plate shape. Further, the waveguide 10 has another end (z-direction positive side) on the side of the second waveguide part 10B through which a signal of a waveguide system is input to the waveguide 10 or output from the waveguide 10. Further, the waveguide 10 includes an internal cavity that stores first to fourth conductive plates 12-15 and the like that will be described later.
When the coaxial waveguide transducer 1 according to this embodiment is used while being connected to a band pass filter or a duplexer, the band pass filter or the duplexer is connected to the other end on the side of the second waveguide part 10B.
Further, the waveguide 10 includes a stepwise step bend part 11 formed in an outer corner part of the bent part 10C. While the number of stages of the step bend part 11 is two in
The first conductive plate 12 and the second conductive plate 13 are plate-like conductors (a first conductor and a second conductor) whose side surfaces are connected to respective inner side walls of the first waveguide part 10A of the waveguide 10 in such a way that they are extended in the direction in which the central conductor 21 of the coaxial line 20 is extended and they are flush with the central conductor 21. The first conductive plate 12 and the second conductive plate 13 are extended to the bent part 10C (that is, to the x-direction negative side with respect to the line C1 shown in
The third conductive plate 14 is a plate-like conductor (third conductor) having one end connected to the central conductor 21 of the coaxial line 20 and the other end connected to the first conductive plate 12, and is arranged obliquely with respect to the direction in which the central conductor 21 of the coaxial line 20 is extended. Note that the other end of the third conductive plate 14 is not limited to being connected to the first conductive plate 12 and may be connected to the second conductive plate 13.
The fourth conductive plate 15 is a plate-like conductor (fourth conductor) that is projected from one end of the third conductive plate 14 toward the second conductive plate 13 in the y-axis positive direction and is arranged in such a way that a gap is formed between the fourth conductive plate 15 and the second conductive plate 13. The resonance point of the coaxial waveguide transducer 1 is changed in accordance with the length of this gap. Therefore, by adjusting the length of the gap between the fourth conductive plate 15 and the second conductive plate 13, the reflection characteristics of the coaxial waveguide transducer 1 can be fine-adjusted. When the other end of the third conductive plate 14 is connected to the second conductive plate 13, the fourth conductive plate 15 is projected toward the first conductive plate 12 in the y-axis negative direction, and is arranged in such a way that a gap is formed between the fourth conductive plate 15 and the first conductive plate 12.
Incidentally, the waveguide 10 is configured to hold a plate-like conductive plate on a horizontal plane by a case (not shown) where a concave part is formed and a cover (not shown) where a concave part is formed. In other words, the waveguide 10 is configured to be divided into the case and the cover on the horizontal plane and to hold the plate-like conductive plate between the case and the cover that have been divided. Therefore, in
Further, the central conductor 21 of the coaxial line 20, the first to fourth conductive plates 12-15 and the like are integrally formed in the conductive plate held by the case and the cover. Therefore, the central conductor 21 of the coaxial line 20, the first to fourth conductive plates 12-15 and the like are positioned on the same plane (horizontal plane in
As described above, the first to fourth conductive plates 12-15 and the central conductor 21 of the coaxial line 20 are formed of the same material since they are integrally formed in the conductive plate held between the case and the cover. It is sufficient that the material of the first to fourth conductive plates 12-15 and the central conductor 21 be metal having a high conductivity such as copper. Further, the material of the first to fourth conductive plates 12-15 and the central conductor 21 may be an insulator such as plastic whose surface is plated with a highly conductive metal.
In this embodiment, when a signal of the coaxial line system is input to one end (x-direction positive side) of the waveguide 10 on the side of the first waveguide part 10A, the signal of this coaxial line system is transduced into a signal of the waveguide system, the transduced signal proceeds to the x-direction negative side, then the signal path is bent at a substantially right angle on the z-direction positive side in the step bend part 11, and the resulting signal is output from the other end (z-direction positive side) of the waveguide 10 on the side of the second waveguide part 10B.
On the other hand, when a signal of the waveguide system is input to the other end (z-direction positive side) of the waveguide 10 on the side of the second waveguide part 10B, this signal of the waveguide system proceeds to the z-direction negative side, the signal path is bent at a substantially right angle on the x-direction positive side in the step bend part 11, the signal is transduced into a signal of the coaxial line system, and the resulting signal is output from one end (x-direction positive side) of the waveguide 10 on the side of the first waveguide part 10A.
In the coaxial waveguide transducer 1 according to this embodiment, the step bend part 11 is formed in the outer corner part of the L-shaped bent part 10C of the waveguide 10, whereby the size of the part of the coaxial waveguide transducer 1 on the side of the cover is reduced. In order to further reduce this size, a height HB between the bottom surface of the first waveguide part 10A of the waveguide 10 and the central conductor 21 of the coaxial line 20 is lowered.
When, however, the size of the part of the coaxial waveguide transducer 1 on the side of the cover is reduced, as described above, the boundary between the cover and the case (line C3 shown in
In order to solve the above problem, in this embodiment, in the first waveguide part 10A of the waveguide 10 on the side of the coaxial line 20, the first conductive plate 12 and the second conductive plate 13 that are extended in the direction in which the central conductor 21 of the coaxial line 20 is extended are arranged in the respective inner side walls of the first waveguide part 10A, and the third conductive plate 14 that is extended obliquely from the central conductor 21 of the coaxial line 20 and is connected to the first conductive plate 12 is arranged. According to the above configuration, the first waveguide part 10A of the waveguide 10 on the side of the coaxial line 20 is configured to have a form of a ridge waveguide including the first conductive plate 12 and the second conductive plate 13 as ridges, whereby the reflection characteristics can be satisfied.
Referring now to
As shown in
Therefore, it is confirmed that the reflection characteristics can be satisfied within a desired usage band due to the effects of the first conductive plate 12 and the second conductive plate 13 in this embodiment.
In this embodiment, as described above, by adjusting the length of the gap between the fourth conductive plate 15 and the second conductive plate 13, the graph of the reflection characteristics shown in
As described above, in this embodiment, the stepwise step bend part 11 is formed in the outer corner part of the L-shaped bent part 10C of the waveguide 10 having a substantially L shape. It is therefore possible to reduce the size of the coaxial waveguide transducer 1.
Further, in this embodiment, in the first waveguide part 10A of the waveguide 10 on the side of the coaxial line 20, the first conductive plate 12 and the second conductive plate 13 that are extended in the direction in which the central conductor 21 of the coaxial line 20 is extended are arranged in the respective inner side walls of the first waveguide part 10A, and the third conductive plate 14 that is extended obliquely from the central conductor 21 of the coaxial line 20 and is connected to the first conductive plate 12 is arranged. As described above, the first waveguide part 10A of the waveguide 10 on the side of the coaxial line 20 is configured to have a form of the ridge waveguide having the first conductive plate 12 and the second conductive plate 13 as ridges, whereby it is possible to satisfy the reflection characteristics in a desired band.
According to the above discussion, the coaxial waveguide transducer 1 according to this embodiment is able to achieve both miniaturization and satisfaction of the reflection characteristics.
While the present disclosure has been described with reference to the aforementioned embodiment, the present disclosure is not limited to the aforementioned embodiment. Various changes that can be understood by those skilled in the art can be made to the configurations and the details of the present disclosure within the scope of the present disclosure.
For example, while there is an advantage that the shape of the central conductor of the coaxial line and the first to fourth conductors is a plate shape and thus they can be integrally formed in one conductive plate in the aforementioned embodiment, the shape of the central conductor of the coaxial line and the first to fourth conductors is not limited to the plate shape. The shape of the central conductor of the coaxial line and the first to third conductors may be, for example, a columnar shape, a rectangular parallelepiped shape or the like.
Further, while the case in which the coaxial waveguide transducer performs transduction between the coaxial line and the waveguide has been described in the aforementioned embodiment, this is merely an example. The present disclosure can be applied also to a case in which, for example, a planar line such as a stripline or a microstripline is used in place of the coaxial line. In this case, it is possible to perform transduction between these planar lines and the waveguide.
This application is based upon and claims the benefit of priority from Japanese Patent Application No. 2017-140559, filed on Jul. 20, 2017, the disclosure of which is incorporated herein in its entirety by reference.
Number | Date | Country | Kind |
---|---|---|---|
2017-140559 | Jul 2017 | JP | national |
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/JP2018/021137 | 6/1/2018 | WO | 00 |