The present application is based on Japanese patent application No. 2012-264582 filed on Dec. 3, 2012, the entire contents of which are incorporated herein by reference.
1. Field of the Invention
The present invention relates to a transmission line and an antenna device including the transmission line.
2. Description of the Related Art
In an antenna device for a radio communication apparatus, such as a mobile terminal, a transmission line for transmitting high-frequency signals has been used, which forms a distributor or a multiplexer between a high-frequency power source and a transmitting/receiving device. Examples of the transmission line include a microstrip line and a triplate line, which is formed by a pair of outer conductors disposed in parallel with each other and a plate-like central conductor interposed therebetween (see, e.g., Japanese Unexamined Patent Application Publication No. 2003-264420).
A triplate line described in Japanese Unexamined Patent Application Publication No. 2003-264420 includes an inner conductor and a pair of outer conductors facing each other with the inner conductor interposed therebetween, the outer conductors being an outer conductor (first outer conductor) and a reflective plate (second outer conductor). The inner conductor is connected at one end to a feeding transformer in an antenna element, and is connected at the other end to a feeding unit. There is a space between the inner conductor and the first outer conductor, and between the inner conductor and the second outer conductor.
Characteristics of a triplate line of this type tend to be unstable, due to positional displacement of a central conductor or changes in distance between outer conductors. Therefore, particularly when the triplate line is relatively large in size, the central conductor needs to be supported between the outer conductors by a spacer made of an insulator, such as resin.
However, since such a spacer itself has a unique dielectric constant higher than that of air, an impedance in a supported portion of the central conductor supported by the spacer is lower than an impedance in the surrounding area. This results in an impedance mismatch and reflection of high-frequency signals.
As a measure to reduce reflections, the present inventors initially intended to narrow the line width of the supported portion of the central conductor. With this method, the supported portion itself exhibits an impedance higher than that of the surrounding area depending on the line width. Therefore, by setting the line width of the supported portion in consideration of the dielectric constant of the spacer, the impedance in the supported portion can be matched to the characteristic impedance of the triplate line in the surrounding area, and reflections can be reduced.
However, assume for example that the supported portion has a through hole passing therethrough in the direction of thickness of the central conductor, and that the spacer is secured to the supported portion by inserting part of the spacer into the through hole. In this case, the line width of the supported portion is extremely narrow in the area around the through hole. Because this may affect the mechanical strength of the supported portion, it has been difficult in practice to provide such a through hole in the supported portion.
An object of the present invention is to provide a transmission line and an antenna device that can reduce reflections while ensuring strength in a supported portion of a central conductor.
To solve the problems described above, the present invention provides a transmission line that has a triplate line including a pair of outer conductors disposed in parallel with each other at a predetermined interval, and a central conductor disposed in a space between the pair of outer conductors; and a spacer interposed in the space between the pair of outer conductors and the central conductor, the spacer being made of a dielectric material and configured to support the central conductor. The central conductor has a supported portion supported by the spacer, and first and second high-impedance portions having characteristic impedances higher than a characteristic impedance in the supported portion. The first and second high-impedance portions are disposed on input and output sides, respectively, of the supported portion.
According to the present invention, it is possible to reduce reflections while ensuring strength in the supported portion of the central conductor.
A transmission line according to an embodiment of the present invention will now be described with reference to the attached drawings.
As illustrated in
The present embodiment describes an example where the first and second outer conductors 10 and 11 and the central conductor 12 are each formed by a plate-like body made of a conductive metal, such as copper or brass. Alternatively, the first and second outer conductors 10 and 11 and the central conductor 12 may each be formed, for example, by a plate-like resin member covered with metal foil on one or both sides.
The central conductor 12 is rectangular in cross section orthogonal to its extending direction. The thickness of the central conductor 12 is, for example, 1 mm. The distance between the first outer conductor 10 and the second outer conductor 11 is, for example, 5 mm. The cross-sectional shape and the thickness of the central conductor 12 and the distance between the first outer conductor 10 and the second outer conductor 11 may be appropriately determined, for example, by taking a target characteristic impedance of the triplate line 100 into consideration.
The central conductor 12 has a supported portion 122 supported by the dielectric spacer 2, a first high-impedance portion 121 formed on one side (input side) of the supported portion 122 along the extending direction of the central conductor 12, and a second high-impedance portion 123 formed on the other side (output side) of the supported portion 122 along the extending direction of the central conductor 12. In the following description, a substantial part of the central conductor 12 other than the first high-impedance portion 121, the supported portion 122, and the second high-impedance portion 123 will be referred to as a main body 120. The supported portion 122 has a through hole 122a in its center. The through hole 122a passes through the central conductor 12 in the thickness direction.
The line width of the central conductor 12 in the width direction orthogonal to the extending direction of the central conductor 12 (i.e., the right-left direction in
As illustrated in
The second spacer member 22 is a circular plate-like member having a fitting hole 22a in its center. The protrusion 211 of the first spacer member 21 is fitted into the fitting hole 22a. The diameter (outside diameter) and the thickness of the second spacer member 22 are the same as the diameter and the thickness, respectively, of the base 210 of the first spacer member 21. The fitting hole 22a passes through the second spacer member 22 in the thickness direction.
The protrusion 211 of the first spacer member 21 passes through the through hole 122a in the supported portion 122 of the central conductor 12 and is fitted into the fitting hole 22a of the second spacer member 22. The base 210 of the first spacer member 21 is interposed between the second outer conductor 11 and the central conductor 12. The second spacer member 22 is interposed between the first outer conductor 10 and the central conductor 12. The dielectric spacer 2 supports the central conductor 12 at the supported portion 122 by combining the first spacer member 21 and the second spacer member 22 together such that the supported portion 122 of the central conductor 12 is sandwiched therebetween. Hereinafter, a part formed by the first high-impedance portion 121, the supported portion 122, and the second high-impedance portion 123 will be referred to as a support structure part 12a.
When the supported portion 122 of the transmission line 1 is supported by the dielectric spacer 2, a characteristic impedance in the supported portion 122 is lower than a characteristic impedance of the supported portion 122 itself (i.e., a characteristic impedance in the supported portion 122 obtained in the absence of the dielectric spacer 2). In the following description, the characteristic impedance in the supported portion 122 will refer to a characteristic impedance in the supported portion 122 supported by the dielectric spacer 2.
The shape and the structure of the dielectric spacer 2 are not limited to those illustrated in
A characteristic impedance Z1 of the first high-impedance portion 121 and a characteristic impedance Z3 of the second high-impedance portion 123 are higher than a characteristic impedance Z2 in the supported portion 122 supported by the dielectric spacer 2 (Z1>Z2 and Z3>Z2). Preferably, the characteristic impedances Z1 and Z3 of the first high-impedance portion 121 and the second high-impedance portion 123 are higher than a characteristic impedance Z0 of the main body 120 of the central conductor 12. In this case, the characteristic impedance Z2 in the supported portion 122 is lower than or equal to the characteristic impedance Z0 of the main body 120. This means that the inequalities Z1>Z0≧Z2 and Z3>Z0≧Z2 are satisfied. The characteristic impedances Z1 and Z3 of the first high-impedance portion 121 and the second high-impedance portion 123 may either be the same (Z1=Z3) or different (Z1>Z3 or Z1<Z3).
An impedance adjustment between the first high-impedance portion 121 and the second high-impedance portion 123 can be made by setting their line lengths L1 and L3 and the line widths W1 and W3 in accordance with set values of the characteristic impedances Z1 and Z3.
As described above, the first high-impedance portion 121 and the second high-impedance portion 123 having impedances higher than the characteristic impedance Z2 in the supported portion 122 are provided on the input side and the output side, respectively, of the supported portion 122 that lowers its characteristic impedance when it is supported by the dielectric spacer 2. Thus, impedance matching of the entire transmission line 1 is achieved, and reflection of high-frequency signals can be reduced.
Since the line width W2 of the supported portion 122 can be made greater than the line widths W1 and W3 of the first high-impedance portion 121 and the second high-impedance portion 123, the strength of the supported portion 122 can be ensured even when there is the through hole 122a. That is, it is possible to reduce reflections in the transmission line 1 while ensuring the strength of the supported portion 122.
Next, the basic idea of impedance matching will be described using Smith charts.
Next, impedance matching will be described, which is achieved when the line width of the supported portion 122 is increased for greater mechanical strength of the supported portion 122.
Setting the line width W2 and the line length L2 of the supported portion 122 determines the characteristic impedance Z2 of the supported portion 122, and also determines the amount of movement of the impedance from Z4 to Z5 and an angle θ2 in
Specifically, the line length L1 and the line width W1 of the first high-impedance portion 121 are set such that, as illustrated in
Also, the line length L3 and the line width W3 of the second high-impedance portion 123 are set such that, as illustrated in
When the characteristic impedances Z1 and Z3 of the first high-impedance portion 121 and the second high-impedance portion 123 are equal, a relational equation representing the relationship among the characteristic impedances Z0, Z1 (=Z3), and Z2 can be obtained in the following manner.
In a triangle having the characteristic impedances Z2, Z4, and Z1 as its vertices in
where L1 is the line length of the first high-impedance portion 121 and the second high-impedance portion 123, and L2 is the line length of the supported portion 122.
For the triangle illustrated in
where XZ1 and XZ2 can be given by the following equations (Equation 3).
By substituting the equations for XZ1 and XZ2 in Equation 3 into the equation in Equation 2 and expanding and rearranging the resulting equation, a relational equation representing the relationship among three values, the characteristic impedance Z1 of the first high-impedance portion 121 and the second high-impedance portion 123, the characteristic impedance Z0 of the transmission line 1, and the characteristic impedance Z2 of the supported portion 122, is obtained as in the following equation (Equation 4). From the relational equation shown in Equation 4, the characteristic impedance Z1 can be calculated when the characteristic impedance Z0 of the main body 120, the characteristic impedance Z2 of the supported portion 122, and the line lengths L1 and L2 are known.
A distributor 3 illustrated in
The distributor 3 illustrated in
In the distributor 3 illustrated in
The distributor 3 that distributes signals from the high-frequency power source 4 to the plurality of antenna elements 50 has been described with reference to
As illustrated in
The line width W1 and the line length L1 of the first high-impedance portion 121 and the line width W2 and the line length L2 of the supported portion 122, illustrated in
An S-parameter (VSWR) simulation in the frequency range of 1.0 GHz to 3.0 GHz was performed for each of the transmission lines Nos. 1 to 5. A three-dimensional simulator Femtet was used for the simulation.
As is obvious from
This indicates that by adding the first and second high-impedance portions 121 and 123 having a line width of 2.2 mm to 2.9 mm to the supported portion 122 having a line width of 4.0 mm to 5.2 mm, it is possible to achieve impedance matching of the transmission line, lower the VSWR to less than 1.07 in the frequency range of 1.0 GHz to 3.0 GHz, and reduce reflections.
The central conductor 12 of the triplate line 100B extends from a first terminal portion P1, through the support structure part 12a, and is divided into a second terminal portion P2 and a third terminal portion P3. A portion between the second terminal portion P2 and the third terminal portion P3 extends linearly, and there is a T-shaped branch portion P0 between the second terminal portion P2 and the third terminal portion P3. The first high-impedance portion 121 is disposed on one side of the supported portion 122 adjacent to the first terminal portion P1, and the second high-impedance portion 123 is disposed on the other side of the supported portion 122 adjacent to the branch portion P0. The central conductor 12 is disposed between the first outer conductor 10 and the second outer conductor 11 (not shown).
For the triplate line 100B, a simulation was performed to examine how the S-parameter (VSWR) would change when the supported portion 122 was supported by the dielectric spacer 2 and when the supported portion 122 was not supported (in the latter case, the supported portion 122 was in a floating state between the first spacer member 21 and the second spacer member 22). The simulation was performed, using a three-dimensional simulator Femtet, for the case where a signal was input from the first terminal portion P1. The frequency range for the simulation was 1.0 GHz to 3.0 GHz as in Example 1.
(Operations And Effects Of Embodiments)
The following operations and effects can be achieved according to the embodiments described above.
(1) An impedance mismatch caused by the supported portion 122 supported by the dielectric spacer 2 can be relieved by the first high-impedance portion 121 and the second high-impedance portion 123, and reflections in the transmission line 1 can be reduced over a wide frequency range. Impedance matching can be achieved even when the characteristic impedance Z2 in the supported portion 122 is lower than the characteristic impedance Z0 in the main body 120 of the central conductor 12. It is thus possible to support the supported portion 122 with the dielectric spacer 2 while ensuring the strength of the supported portion 122.
(2) The line width W2 of the supported portion 122 is set to be greater than the line width W1 of the first high-impedance portion 121 and the line width W3 of the second high-impedance portion 123. Thus, even when the supported portion 122 has the through hole 122a, the strength of the supported portion 122 can be ensured.
(3) The dielectric spacer 2 is secured to the supported portion 122 by allowing the protrusion 211 of the first spacer member 21 to be inserted into the through hole 122a, so as to support the central conductor 12. Therefore, the dielectric spacer 2 can be reliably prevented from being displaced from the supported portion 122.
(4) Impedance matching can be reliably achieved by setting the characteristic impedance Z1 of the first high-impedance portion 121 and the second high-impedance portion 123, the characteristic impedance Z0 of the main body 120, and the characteristic impedance Z2 of the supported portion 122 such that the relational equation shown in Equation 4 is satisfied.
The embodiments of the present invention described above are not intended to limit the claimed invention. It is to be noted that not all combinations of features described in the embodiments are essential to the means for solving the problems.
The present invention may be appropriately modified and implemented without departing from the scope of the invention. For example, in the embodiments described above, the strength of the supported portion 122 is ensured by setting the line width W2 of the supported portion 122 to be greater than the line width W1 of the first high-impedance portion 121 and the line width W3 of the second high-impedance portion 123. However, the strength of the supported portion 122 may also be ensured, for example, by setting the thickness of the supported portion 122 to be greater than those of the first high-impedance portion 121 and the second high-impedance portion 123. Even in this case, the operations and effects similar to those in the embodiments described above can be achieved.
In the embodiments described above, the supported portion 122 has the through hole 122a, into which the protrusion 211 of the first spacer member 21 is inserted to secure the dielectric spacer 2 to the central conductor 12. However, the configuration is not limited to this. Instead of forming the through hole 122a in the supported portion 122, an adhesive or the like may be used to secure a spacer made of a dielectric material between the supported portion 122 and the first and second outer conductors 10 and 11. In this case, again by setting the line width W2 of the supported portion 122 to be greater than the line width W1 of the first high-impedance portion 121 and the line width W3 of the second high-impedance portion 123, the spacer can be firmly secured to the supported portion 122 because of the resulting increase in adhesion area.
(SUMMARY OF EMBODIMENTS)
Technical ideas conceivable from the embodiments described above will now be described using reference numerals used in the embodiments. Note that the reference numerals in the following description are not intended to limit the elements of the claims to specific members described in the embodiments.
[1] A transmission line (1) having a triplate line (100) including a pair of outer conductors (10, 11) disposed in parallel with each other at a predetermined interval, and a central conductor (12) disposed in a space between the pair of outer conductors (10, 11); and a spacer (2) interposed in the space between the pair of outer conductors (10, 11) and the central conductor (12), the spacer (2) being made of a dielectric material and configured to support the central conductor (12), wherein the central conductor (12) has a supported portion (122) supported by the spacer (2), and first and second high-impedance portions (121, 123) having characteristic impedances (Z1, Z3) higher than a characteristic impedance (Z2) in the supported portion (122), the first and second high-impedance portions (121, 123) being disposed on input and output sides, respectively, of the supported portion (122).
[2] The transmission line (1) according to [1], wherein a line width (W2) in the supported portion (122) is greater than line widths (W1, W3) in the first and second high-impedance portions (121, 123).
[3] The transmission line (1) according to [1] or [2], wherein the spacer (2) has a first spacer member (21) having a plate-like base (210) and a protrusion (211) protruding from the base (210), and a second spacer member (22) having a fitting hole (22a) into which the protrusion (211) is fitted; and the supported portion (122) is supported by being sandwiched between the base (210) of the first spacer member (21) and the second spacer member (22), and has a through hole (122a) into which the protrusion (211) is inserted.
[4] The transmission line (1) according to any one of [1] to [3], wherein a relationship represented by Equation 4 described above is satisfied, where Z0 is a characteristic impedance of a main body (120) of the triplate line (100), Z1 is a characteristic impedance of both the first and second high-impedance portions (121, 123), Z2 is a characteristic impedance in the supported portion (122) supported by the spacer (2), L1 is a line length of both the first and second high-impedance portions (121, 123), and L2 is a line length of the supported portion (122).
[5] The transmission line (1) according to any one of [1] to [4], wherein the transmission line (1) is applied to a distributor (3) placed between a transmitting device (4) and a plurality of antenna elements (50) or to a multiplexer placed between the plurality of antenna elements (50) and a receiving device.
[6] An antenna device (5) including the transmission line (1) according to any one of [1] to [4], and an antenna element (50).
Number | Date | Country | Kind |
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2012-264582 | Dec 2012 | JP | national |
Number | Name | Date | Kind |
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3560896 | Essinger | Feb 1971 | A |
4365222 | Lampert | Dec 1982 | A |
5790002 | Fischer | Aug 1998 | A |
6600395 | Handforth | Jul 2003 | B1 |
6816039 | Taylor | Nov 2004 | B1 |
20090174609 | Sanada | Jul 2009 | A1 |
Number | Date | Country |
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H 4-019003 | Feb 1992 | JP |
2000-031709 | Jan 2000 | JP |
2003-264420 | Sep 2003 | JP |
2004-320521 | Nov 2004 | JP |
Entry |
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Cohn “Characteristic Impedance of the Shielded-Strip Transmission Line” Transactions of the IRE Professional Group on Microwave Theory and Techniques (vol. 2 , Issue: 2), Jan. 6, 2003. |
Japanese Office Action dated Dec. 1, 2015 with an English translation. |
Number | Date | Country | |
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20140152525 A1 | Jun 2014 | US |