This application is the national phase under 35 U.S.C. § 371 of PCT International Application No. PCT/JP03/03631 which has an International filing date of Mar. 25, 2003, which designated the United States of America.
The present invention relates to a rotary joint mainly used in a VHF band, a UHF band, a microwave band and a millimeter band.
The choke groove 103 is the means which is usually used so that a gap defined between the circular waveguides 101 and 102 becomes equivalently short-circuit in a frequency of an electric wave propagated through the circular waveguides 101 and 102. The circular waveguides 101 and 102 are connected to each other in terms of a high frequency by a function of the connection portion 105 having the choke groove 105 while keeping a predetermined gap therebetween. The circular waveguide 102 can be rotated about a tube axis with respect to the circular waveguide 102 by a predetermined angle of rotation by a function of the bearing 104 while keeping the tube axis so that the circular waveguides 101 and 102 are aligned with each other through the tube axis.
The position of the projection portion 106 for conversion from a linearly polarized wave to a circularly polarized wave is set to the position making an angle of +45 degrees or −45 degrees with a direction of an electric field of a TE10-mode of the input rectangular waveguide 108. At this time, the position of the projection portion 107 for conversion from a linearly polarized wave to a circularly polarized wave is set to the position which, for the former, makes an angle of −45 degrees with a direction of an electric field of a TE10-mode of the output rectangular waveguide 110, and which, for the latter, makes an angle of +45 degrees. The coupling holes 114 and 116 are formed by cutting off parts of the short-circuit plates 112 and 113, respectively. The coupling holes 115 and 117 are formed by cutting off parts of sidewalls of the circular waveguides 101 and 102, respectively.
Next, operation will hereinbelow be described. After an electric wave of a TE10-mode made incident from the input rectangular waveguide 108 has been efficiently converted into the electric wave of a TE11-mode in the circular waveguide 101 through the coupling hole 114 now, it is then converted from the linearly polarized wave into the circularly polarized wave by the projection portion 106 for conversion from a linearly polarized wave into a circularly polarized wave. The circularly polarized wave obtained through the conversion is transmitted to the circular waveguide 102 through the connection portion 105 irrespective of an angle of rotation of the circular waveguide 102 due to the rotation symmetry of the mode to be guided into the output rectangular waveguide 110 through a course reverse to the above-mentioned course. That is to say, after the electric wave has been converted from the circularly polarized wave into the linearly polarized wave by the projection portion 107 for conversion from a linearly polarized wave into a circularly polarized wave in the circular waveguide 102, it is then transmitted to the output rectangular waveguide 110 through the coupling hole 116.
On the other hand, other electric waves of a TE10-mode made incident from the input rectangular waveguide 109 is efficiently converted into the electric wave of a TE11-mode in the circular waveguide 101 through the coupling hole 115. At this time, a direction of the electric field of the TE11-mode obtained through the conversion perpendicularly intersects that of the TE11-mode due to the incident wave from the input rectangular waveguide 108. For this reason, the electric wave of the TE11-mode obtained through the conversion via the coupling hole 115 is converted into a circularly polarized wave having rotation reverse to that of the TE11-mode through the coupling hole 114 by the projection portion 106 for conversion from a linearly polarized wave into a circularly polarized wave. At this time, the circularly polarized wave obtained through the conversion is transmitted to the circular waveguide 102 through the connection portion 105 irrespective of an angle of rotation of the circular waveguide 102 due to the rotation symmetry of the mode to be guided to the output rectangular waveguide 111 through a course reverse to the above-mentioned course. That is to say, after the electric wave has been converted from the circularly polarized wave into the linearly polarized wave by the projection portion 107 for conversion from a linearly polarized wave into a circularly polarized wave in the circular waveguide 102, it is then transmitted to the output rectangular waveguide 111 through the coupling hole 117.
As described above, in the conventional rotary joint shown in
In the conventional rotary joint, for obtaining a circularly polarized wave having excellent axial ratio characteristics, the projection portions 106 and 107 for conversion from a linearly polarized wave into a circularly polarized wave need to be provided so as to be relatively long. Thus, there is encountered a problem in that the total length becomes long.
In addition, in general, in the projection portions 106 and 107 for conversion from a linearly polarized wave into a circularly polarized wave, a frequency range in which a circularly polarized wave with excellent axial ratio characteristics is obtained is relatively narrow. Thus, there is encountered a problem in that the excellent axial ratio characteristics of a broad band are difficult to be obtained for a rotary joint as well.
The present invention has been made in order to solve the above-mentioned problems, ant it is, therefore, an object of the present invention to provide a rotary joint which is of a thin type and has broad band characteristics and which is low in loss and is excellent in power resistance.
A rotary joint according to the present invention includes: first and second polarizers each having a common side terminal connected to a waveguide portion, and two branch side terminals through which two polarized waves orthogonal to each other inputted through the common side terminal are separately taken out; and the waveguide portion which has a rotatable connection portion, one end of which is connected to the common side terminal of the first polarizer and the other end of which is connected to the common side terminal of the second polarizer.
Description will hereinbelow be given with respect to the operation of the rotary joint according to the first embodiment of the present invention with reference to
Here, for the electric wave H, each of vertical sidewall intervals of the rectangular branch waveguides 2c and 2d is designed so as to be equal to or smaller than a half of the free-space wavelength of the used frequency band. Thus, the electric wave H hardly leaks to the sides of the terminals P31 and P32 due to these cut-off effects. In addition, as shown in
Moreover, for the circular-square waveguide step 9, the stepped portion thereof is designed so as to be much smaller than the free-space wavelength of the used frequency band. For this reason, with respect to the reflection characteristics thereof, a reflection loss is large in the frequency band in the vicinity of a cut-off frequency of the basic mode of the electric wave H, while it is very small in the high frequency band higher than the cut-off frequency to some extent. This is similar to the reflection characteristics of the above-mentioned branch portion. Consequently, the circular-square waveguide step 9 is installed in the position where a reflected wave from the branch portion and a reflected wave due to the circular-square waveguide step 9 cancel each other in the vicinity of the cut-off frequency, whereby the degradation of the reflection characteristics due to the frequency band in the vicinity of the cut-off frequency can be suppressed without injuring the excellent reflection characteristics in the frequency band higher than the cut-off frequency of the basic mode of the electric wave H to some extent.
On the other hand, assuming that the vertically polarized electric wave V of the basic mode (TE10-mode) is inputted through the terminal P1, this electric wave is propagated through the circular-square waveguide step 9, the square main waveguide 1, and the rectangular branch waveguides 2c and 2d to be outputted as the electric wave of the basic mode (TE10-mode) in each branch waveguide through the terminals P31 and P32.
Here, for the electric wave V, each of vertical sidewall intervals of the rectangular branch waveguides 2a and 2b is designed so as to be equal to or smaller than a half of the free-space wavelength of the used frequency band. Thus, the electric wave V hardly leaks to the sides of the terminals P21 and P22 due to these cut-off effects. In addition, similarly to the case of the electric wave H, since a direction of the electric field can be changed along the metallic block 4 and the short-circuit plate 3, there is provided the electric field distribution in a state in which two rectangular waveguide E-plane miter bends which are excellent in reflection characteristics are equivalently, symmetrically placed. As a result, the electric wave V inputted through the terminal P1 is efficiently outputted to the terminals P31 and P32 while suppressing the reflection to the terminal P1 and the leakage to the terminals P21 and P22.
Moreover, for the circular-square waveguide step 9, the stepped portion thereof is designed so as to be much smaller than the free-space wavelength of the used frequency band. For this reason, with respect to the reflection characteristics thereof, a reflection loss is large in the frequency band in the vicinity of the cut-off frequency of the basic mode of the electric wave V, while it is very small in the frequency band higher than the cut-off frequency to some extent. This is similar to the reflection characteristics of the above-mentioned branch portion. Consequently, the circular-square waveguide step 9 is installed in the position where a reflected wave from the branch portion and a reflected wave due to the circular-square waveguide step 9 cancel each other in the vicinity of the cut-off frequency, whereby the degradation of the reflection characteristics due to the frequency band in the vicinity of the cut-off frequency can be suppressed without injuring the excellent reflection characteristics in the frequency band higher than the cut-off frequency of the basic mode of the electric wave V to some extent.
The above-mentioned operation principles have been described with reference to the case where the terminal P1 is set as an input terminal, and the terminals P21 to P32 are set as output terminals. However, the above-mentioned operation principles are applied to a case as well where the terminals P21 to P32 are set as input terminals, the terminal P1 is set as an output terminal, input waves inputted through the terminals P21 and P22 are made 180 degrees out of phase with each other, and are made equal in amplitude to each other, and input waves inputted through the terminals P31 and P32 are made 180 degrees out of phases with each other and are made equal in amplitude to each other.
Next, description will hereinbelow be given with respect to the operation of the polarizer of
Here, for the electric wave H, each of the vertical sidewall intervals of the rectangular branch waveguides 2c and 2d is designed so as to be equal to or smaller than a half of the free-space wavelength of the used frequency band. Thus, the electric wave H hardly leaks to the sides of the rectangular waveguides 2c and 2d due to these cut-off effects. In addition, as shown in
Moreover, for the circular-square waveguide step 9, the stepped portion thereof is designed so as to be much smaller than the free-space wavelength of the used frequency band. For this reason, with respect to the reflection characteristics thereof, a reflection loss is large in the frequency band in the vicinity of the cut-off frequency of the electric wave H of the basic mode, while it is very small in the high frequency band higher than the cut-off frequency to some extent. This is similar to the reflection characteristics of the above-mentioned branch portion. Consequently, the circular-square waveguide step 9 is installed in the position where a reflected wave from the branch portion and a reflected wave due to the circular-square waveguide step 9 cancel each other in the vicinity of the cut-off frequency, whereby the degradation of the reflection characteristics due to the frequency band in the vicinity of the cut-off frequency can be suppressed without injuring the excellent reflection characteristics in the frequency band higher than the cut-off frequency of the electric wave H of the basic mode to some extent.
Furthermore, the rectangular waveguide multistage transformers 11a and 11b are curved with the tube axes thereof, and have a plurality of stepped portions provided on the upper sidewalls thereof, and also each of intervals of the stepped portions is made about ¼ of a guide wavelength with respect to a waveguide central line. Thus, finally, the electric waves in the rectangular branch waveguides 2a and 2b which are obtained by separating the electric wave H thereinto can be composed in the rectangular waveguide E-plane T-branch circuit 12a to be efficiently outputted to the terminal P2 without injuring the reflection characteristics.
On the other hand, assuming that the vertically polarized electric wave V of a basic mode (TE10-mode) is inputted through the terminal P1, this electric wave is propagated through the circular-square waveguide step 9, the square main waveguide 1, the rectangular branch waveguides 2b and 2d, and the rectangular waveguide multistage transformers 11c and 11d to be composed in the rectangular waveguide E-plane T-branch circuit 12b again to be outputted as the electric wave of the basic mode (TE10-mode) in each branch waveguide through the terminal P3.
Here, for the electric wave V, each of the vertical sidewall intervals of the rectangular branch waveguides 2a and 2b is designed so as to be equal to or smaller than a half of the free-space wavelength of the used frequency band. Thus, the electric wave V hardly leaks to the sides of the rectangular waveguides 2a and 2b due to these cut-off effects. In addition, similarly to the case of the electric wave H, since a direction of the electric field can be changed along the metallic block 4 and the short-circuit plate 3, there is provided the electric field distribution in a state in which two rectangular waveguide E-plane miter bends which are excellent in reflection characteristics are equivalently, symmetrically placed. As a result, the electric wave V inputted through the terminal P1 is efficiently outputted to the rectangular waveguides 2c and 2d while suppressing the reflection to the terminal P1 and the leakage to the rectangular waveguides 2a and 2b.
Moreover, for the circular-square waveguide step 9, the stepped portion thereof is designed so as to be much smaller than the free-space wavelength of the used frequency band. For this reason, with respect to the reflection characteristics thereof, a reflection loss is large in the frequency band in the vicinity of the cut-off frequency of the electric wave V of the basic mode, while it is very small in the high frequency higher than the cut-off frequency to some extent. This is similar to the reflection characteristics of the above-mentioned branch portion. Consequently, the circular-square waveguide step 9 is installed in the position where a reflected wave from the branch portion and a reflected wave due to the circular-square waveguide step 9 cancel each other in the vicinity of the cut-off frequency, whereby the degradation of the reflection characteristics due to the frequency band in the vicinity of the cut-off frequency can be suppressed without injuring the excellent reflection characteristics in the frequency band higher than the cut-off frequency of the electric wave V of the basic mode to some extent.
Furthermore, the rectangular waveguide multistage transformers 11c and 11d are curved with the tube axes thereof, and have a plurality of stepped portions provided on the lower sidewalls thereof, and also each of intervals of the stepped portions is made about ¼ of a guide wavelength with respect to a waveguide central line. Thus, finally, the electric waves in the rectangular branch waveguides 2c and 2d which are obtained by separating the electric wave V thereinto can be composed in the rectangular waveguide E-plane T-branch circuit 12b so as to avoid interference with the rectangular waveguide multistage transformers 11a and 11b, and the rectangular waveguide E-plane T-branch circuit 12a to be efficiently outputted to the terminal P3 without injuring the reflection characteristics.
The above-mentioned operation principles have been described with respect to the case where the terminal P1 is set as an input terminal, and the terminals P2 and P3 are set as output terminals. However, the above-mentioned operation principles are applied to a case as well where the terminals P2 and P3 are set as input terminals, and the terminal P1 is set as an output terminal.
Moreover, description will hereinbelow be given with respect to the operation of the circular waveguide rotation portion of
The operations of the respective portions in
Here, when the circular waveguide 14 and the polarizer 22 are mechanically connected to each other to be simultaneously rotated, a polarized wave angle of the polarized wave of the circular waveguide TE11-mode guided to the polarizer 22 is changed in accordance with an angle of rotation of the circular waveguide 14, and the amplitudes of the electric waves guided to the terminals P5 and P6, respectively, are changed accordingly. At this time, no reflection is caused in the polarizer 22 and the circular waveguide rotation portion 23.
On the other hand, after two electric waves which are 90 degrees out of phase with each other, but are equal in amplitude to each other have been made incident through the terminals P2 and P3, respectively, these electric waves are composed from the form of two orthogonal polarized waves in the inside of the polarizer 21 into a circularly polarized wave of the circular waveguide TE11-mode which is in turn guided to the terminal P1. After this composite wave has been transmitted through the circular waveguide rotation portion 23, it is separated into the two orthogonal polarized waves again in the polarizer 22 which are in turn distributively outputted to the terminals P5 and P6, respectively.
Here, when the circular waveguide 14 and the polarizer 22 are mechanically connected to each other to be simultaneously rotated, due to the axial symmetrical property of the circularly polarized wave, two electric waves which are 90 degrees out of phase with each other and which are equal in amplitude to each other are distributively outputted to the terminals P5 and P6, respectively, without being reflected in the polarizer 22 and the circular waveguide rotation portion 23 irrespective of presence or absence of rotation of the circular waveguide 14 and the polarizer 22.
Consequently, the invention of the first embodiment shown in
As described above, the rotary joint according to the first embodiment has an effect and a superior advantage in that the rotary joint is of a thin type and has broad band characteristics since the polarizers 21 and 22 can be constructed so as to be of a thin type and to have the broad band, and also a circularly polarized wave generating portion is unnecessary which has a long axial length and a relatively narrow frequency band. In addition, the rotary joint has a superior advantage in that since the rotary joint is constructed with only the waveguides, it is low in loss and is excellent in power resistance as well.
Note that, in the first embodiment of the present invention, the description has been given with respect to the case where in
In addition, while in the first embodiment of the present invention, the description has been given with respect to the case where the circular waveguide is used in
In addition, in the first embodiment of the present invention, the description has been given with respect to the case where the quadratic spindle-shaped metallic block 4 is provided in order to change a direction of the electric field as shown in
In addition, in the first embodiment of the present invention, the description has been given with respect to the case where there is used the circular-square waveguide step 9 which is connected to one terminal of the square main waveguide 1, and an opening diameter of which becomes narrower towards the above-mentioned branch portion, and also a stepped portion of which is much smaller than the free-space wavelength of the used frequency band. However, even if there is used a circular-square waveguide step an opening diameter of which is increased towards the above-mentioned branch portion.
In a second embodiment of the present invention, description will hereinbelow be given with respect to a case where a hybrid is added to the rotary joint of the above-mentioned first embodiment.
The operation will hereinbelow be described. An electric wave made incident through the terminal P7 is distributed in the form of two electric waves which are 90 degrees out of phase with each other and which are equal in amplitude to each other by the 90 degrees hybrid 24 to the terminals P2 and P3, respectively. These electric waves obtained through the distribution are composed in the form of a circularly polarized wave in the polarizer 21. Thus, the composite wave is guided to the polarizer 22 to be redistributed in the form of two electric waves which are 90 degrees out of phase with each other and which are equal in amplitude to each other irrespective of an angle of rotation of the circular waveguide rotation portion 23 to the terminals P5 and P6, respectively.
As described above, the rotary joint according to the second embodiment of the present invention has the same function, effects and superior advantage as those of the invention of the above-mentioned first embodiment, and in addition thereto, has an effect and a superior advantage in that two electric waves can be transmitted irrespective of an angle of rotation of the circular waveguide rotation portion 23.
In a third embodiment of the present invention, description will hereinbelow be given with respect to a case where a 90-degrees hybrid and phase shifters are added to the rotary joint of the above-mentioned second embodiment.
Operation will hereinbelow be described. The 90 degrees hybrids 24 and 25, and the phase shifters 26 and 27 constitute a variable power distributor which is commonly used. An electric wave made incident through the terminal P11 is changed so that absolute values of quantities of phase shift in both the phase shifters become equal to each other with a passage phase in the phase shifter 26 falling within the range of 0 degree to −90 degrees and with a passage phase in the phase shifter 27 falling within the range of 0 degree to +90 degrees, whereby it is distributed in the form of two electric waves which are in phase with each other and which have an arbitrary distribution ratio to the terminals P7 and P8, respectively. Thus, an angle of the polarized wave of a circular waveguide TE11-mode which is obtained through the composition in the polarizer 21 is adjusted by changing quantities of phase shift of the phase shifters 26 and 27 in accordance with an angle of rotation by the circular waveguide rotation portion 23, whereby the two electric waves which are in phase with each other and which have an arbitrary amplitude ratio are guided to the terminals P5 and P6, respectively.
As described above, the rotary joint according to the third embodiment of the present invention has the same function, effects and superior advantage as those of the invention of the above-mentioned first embodiment, and in addition thereto, has an effect and a superior advantage in that the electric wave can be redistributed or recomposed with an equal phase being held and at an arbitrary distribution ratio in upper and lower portions of the circular waveguide rotation portion 23.
In a fourth embodiment of the present invention, description will hereinafter be given with respect to a case where a square waveguide step and a square waveguide are used instead of the circular-square waveguide step 9 and the circular waveguide 10 in the rotary joint of the above-mentioned first embodiment.
The rotary joint according to the fourth embodiment of the present invention has the same operation principles, function, effects and superior advantage as those of the invention of the above-mentioned first embodiment, and in addition thereto, has an effect and a superior advantage in that a range of impedance matching as a polarizer is extended since the waveguide step is different in shape and also is different in reflection amplitude phase by using the square waveguide step 7 and the square waveguide 8.
Note that, while in the fourth embodiment of the present invention, the description has been given with respect to the case where the square waveguide step 7 and the square waveguide 8 are used, a circular waveguide step and a circular waveguide may also be used.
In a fifth embodiment of the present invention, description will hereinbelow be given with respect to a case where a square waveguide step and a square waveguide are further added to the portions as the circular-square waveguide step 9 and the circular waveguide 10 in the rotary joint of the above-mentioned first embodiment.
In the rotary joint according to the fifth embodiment of the present invention, the circular-square waveguide step 9, the square main waveguide 8, and the square waveguide step 7 are operated in the form of a circular-square waveguide multistage transformer. Thus, a diameter of the circular main waveguide 10, a diameter of the square main waveguide 8, and a tube axis length of the square main waveguide 8 are suitably designed, whereby the rotary joint according to the fifth embodiment of the present invention has the same function, effects and superior advantage as those of the invention of the above-mentioned first embodiment, and in addition thereto, has an effect and a superior advantage in that broad band impedance matching is obtained.
As set forth hereinabove, according to the rotary joint of the present invention, the rotary joint includes first and second polarizers each having a common side terminal and two branch side terminals through which two polarized waves orthogonal to each other inputted through the common side terminal are separately taken out, and a circular or square waveguide portion which has a rotatable connection portion, one end of which is connected to the common side terminal of the first polarizer, and the other end of which is connected to the common side terminal of the second polarizer, whereby there is offered an effect that the rotary joint is of a thin type and has broad band characteristics.
In addition, the rotary joint includes a 90 degrees hybrid having first to fourth terminals, and then the second terminal of the 90 degrees hybrid is connected to one branch side terminal of the first polarizer, and the third terminal of the 90 degrees hybrid is connected to the other branch side terminal of the first polarizer, whereby two electric waves can be transmitted independently of an angle of rotation of the rotatable connection portion of the circular or square waveguide.
In addition, the rotary joint includes first and second 90 degrees hybrids each having first to fourth terminals, and first and second phase shifters, and then the second terminal of the first 90 degrees hybrid is connected to the third terminal of the second 90 degrees hybrid through the first phase shifter, the third terminal of the first 90 degrees hybrid is connected to the second terminal of the second 90 degrees hybrid through the second phase shifter, the first terminal of the second 90 degrees hybrid is connected to one branch side terminal of the first polarizer, and the fourth terminal of the second 90 degrees hybrid is connected to the other branch side terminal of the first polarizer, whereby an electric wave can be redistributed or recomposed with an equal phase being held and at an arbitrary distribution ratio in upper and lower portions of the rotatable connection portion of the circular or square waveguide.
In addition, since the circular or square waveguide portion has a cross sectional size with which only an electric wave of a circular waveguide TE11-mode or a square waveguide TE10-mode can be propagated, there is offered an effect in that the rotary joint is of a thin type and has broad band characteristics.
Moreover, since the connection portion of the circular or square waveguide portion includes a choke construction and a rotation mechanism which are formed from a sidewall of the circular or square waveguide portion towards the outside, there is offered an effect in that the rotary joint is of a thin type and has broad band characteristics.
Moreover, in the 90 degrees hybrid, the first terminal is an input terminal, second and third terminals are distribution terminals, and the fourth terminal is an isolation terminal, and then a passage phase of an electric wave from the first terminal to the second terminal and a passage phase of an electric wave from the first terminal to the third terminal have a relative difference of about 90 degrees, and a passage phase of the electric wave from the fourth terminal to the second terminal and a passage phase of the electric wave from the fourth terminal to the third terminal also have a relative difference of about 90 degrees, whereby two electric waves can be transmitted independently of an angle of rotation of the rotatable connection portion of the circular or square waveguide.
Moreover, the polarizer includes: a first main waveguide having a circular or square cross section; a first to fourth rectangular branch waveguides each of which branches nearly perpendicularly to the first main waveguide; a short-circuit plate connected to one terminal of the first main waveguide; a metallic projection provided on the short-circuit plate; one waveguide step which is connected to the other terminal of the first main waveguide and an opening diameter of which becomes narrower towards the branch waveguide side; and a second main waveguide having a circular or square cross section and connected to the waveguide step, whereby there is offered an effect in that the rotary joint is of a thin type and has broad band characteristics.
Also, the polarizer includes: a first main waveguide having a square cross section; first to fourth rectangular branch waveguides each of which branches nearly perpendicularly to the first main waveguide; a short-circuit plate connected to one terminal of the first main waveguide; a metallic projection provided on the short-circuit plate; one circular-square waveguide step connected to the other terminal of the first main waveguide; and a second main waveguide having a circular cross section and connected to the circular-square waveguide step, whereby there is offered an effect in that the rotary joint is of a thin type and has broad band characteristics.
Also, the polarizer includes: a first main waveguide having a circular or square cross section; first to fourth rectangular branch waveguides each of which branches nearly perpendicularly to the first main waveguide; a short-circuit plate connected to one terminal of the first main waveguide; a metallic projection provided on the short-circuit plate; one waveguide step which is connected to the other terminal of the first main waveguide and an opening diameter of which is increased towards the branch waveguide side; and a second main waveguide having a circular or square cross section and connected to the waveguide step, whereby there is offered an effect in that the rotary joint is of a thin type and has broad band characteristics.
Also, the polarizer includes: a first main waveguide having a square cross section; first to fourth rectangular branch waveguides each of which branches nearly perpendicularly to the first main waveguide; a short-circuit plate connected to one terminal of the first main waveguide; a metallic projection provided on the short-circuit plate; one square waveguide step which is connected to the other terminal of the first main waveguide and an opening of which is decreased towards the branch waveguide side; a second main waveguide having a square cross section and connected to the square waveguide step; one circular-square waveguide step connected to the second square main waveguide; and a third main waveguide having a circular cross section and connected to the circular-square waveguide step, whereby there is offered an effect in that broad band impedance matching is obtained.
In addition, a metallic block having one quadratic spindle-shaped or step-shaped or circular cutout is provided as the metallic projection, whereby there is offered an effect in that the rotary joint is of a thin type and has broad band characteristics.
In addition, two sheets of thin metallic plates each having a circular or linearly or step-shaped cutout are provided so as to be perpendicularly intersect each other as the metallic projection, whereby there is offered an effect in that the rotary joint is of a thin type and has broad band characteristics.
Also, the polarizer includes: a first rectangular waveguide multistage transformer which is connected to the first branch waveguide and which has a curved tube axis; a second rectangular waveguide multistage transformer which is connected to the second branch waveguide and which has a curved tube axis; a first rectangular waveguide E-plane T-branch circuit connected to the first and second rectangular waveguide multistage transformers; a third rectangular waveguide multistage transformer which is connected to the third branch waveguide and which has a curved tube axis; a forth rectangular waveguide multistage transformer which is connected to the fourth branch waveguide and which has a curved tube axis; and a second rectangular waveguide E-plane T-branch circuit connected to the third and fourth branch waveguides, whereby there is offered an effect in that the rotary joint is of a thin type and has broad band characteristics.
As set forth, according to the present invention, it is possible to provide the rotary joint which is of a thin type and has broad band characteristics, and which is low in loss and is excellent in power resistance as well.
Number | Date | Country | Kind |
---|---|---|---|
2002-099537 | Apr 2002 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/JP03/03631 | 3/25/2003 | WO | 00 | 10/21/2003 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO03/083987 | 10/9/2003 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
2686901 | Dicke | Aug 1954 | A |
2714707 | Zabel | Aug 1955 | A |
2892982 | Allen | Jun 1959 | A |
2965898 | Lewis | Dec 1960 | A |
3715688 | Woodward | Feb 1973 | A |
4492938 | Young | Jan 1985 | A |
4847574 | Gauthier et al. | Jul 1989 | A |
6150899 | Seewig et al. | Nov 2000 | A |
6388537 | Matsumoto | May 2002 | B1 |
6489855 | Kitamori et al. | Dec 2002 | B1 |
Number | Date | Country |
---|---|---|
53-53239 | May 1978 | JP |
56-51522 | Dec 1981 | JP |
59-62226 | Apr 1984 | JP |
59-44801 | Nov 1984 | JP |
60058701 | Apr 1985 | JP |
62-51801 | Mar 1987 | JP |
6-85502 | Mar 1994 | JP |
10-32406 | Feb 1998 | JP |
11-330801 | Nov 1999 | JP |
2001-345602 | Dec 2001 | JP |
WO 03083987 | Oct 2003 | WO |
Number | Date | Country | |
---|---|---|---|
20040135657 A1 | Jul 2004 | US |