JP3905341B2 - Converter for satellite broadcasting reception - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a satellite broadcast receiving converter capable of receiving radio waves transmitted from a plurality of adjacent satellites.
[0002]
[Prior art]
In a satellite broadcast receiving converter that receives radio waves transmitted from a plurality of adjacent satellites, for example, the separation angle between two satellites launched into the sky is small, and the radio waves transmitted from these two satellites are transmitted to one outdoor on the ground. When receiving with an antenna device, it is necessary to install two waveguides opposite to the reflecting mirror in the outdoor antenna device.
[0003]
Conventionally, as an example of such a two-satellite broadcast receiving converter, two waveguides having the same structure as that for one satellite are used, and these waveguides are arranged in parallel and faced to a reflecting mirror. Are known. In this case, the opening end faces of the two waveguides arranged in parallel are located in the same plane, and the radio waves transmitted from the two satellites having a predetermined separation angle are reflected by the reflecting mirror, respectively. The two waveguides are configured to enter the inside from the open ends.
[0004]
In addition, as another conventional example of such a dual-satellite broadcast receiving converter, two waveguides are integrally die-cast with an alloy such as aluminum or zinc, and the waveguides and their openings are reflected in an inclined state. What is installed opposite to the mirror is known. In this case, the open end faces of the two waveguides are located in different V-shaped planes, and the radio waves transmitted from two satellites having a predetermined separation angle are reflected by the reflecting mirrors, respectively. The two waveguides are configured to be incident on the inside perpendicularly to the opening end faces.
[0005]
[Problems to be solved by the invention]
By the way, in the former type in which the two waveguides are arranged in parallel among the above-described prior arts, the waveguide for one satellite can be used as it is for two satellites, so the manufacturing cost can be reduced by sharing the parts. There is an advantage that a surge can be suppressed. However, since the open end faces of two waveguides arranged in parallel are located in the same plane, the radio waves of two satellites having a predetermined separation angle are reflected by a common reflecting mirror, and each waveguide When the light is incident on the reflector, there is a lot of useless portions where only the radio wave of one satellite is reflected on the reflector, and a large reflector is inevitably used.
[0006]
On the other hand, in the latter type in which the two waveguides are inclined, a desired preset angle is set in advance on the opening end faces of the two waveguides, so that the radio waves of the two satellites are shared by the reflectors. The light can be reflected by the portion and can enter the respective waveguides, and accordingly, a small reflecting mirror can be used. However, in order to integrate two waveguides, a complicated structure and an expensive die-casting mold are required, so there is a problem that the manufacturing cost of the satellite broadcast receiving converter increases, and Since it is necessary to change the inclination angle of the two waveguides in accordance with the separation angle of the satellite, there is a problem that there is no versatility.
[0007]
The present invention has been made in view of the actual situation of the prior art, and an object of the present invention is to provide a satellite broadcast receiving converter that can reduce the manufacturing cost and has high versatility.
[0008]
[Means for Solving the Problems]
In order to achieve the above object, the present invention provides a plurality of waveguides that are installed opposite to reflecting mirrors that reflect radio waves transmitted from a plurality of adjacent satellites, and whose respective axes are parallel to each other, and these waveguides. A waterproof cover made of a dielectric material disposed so as to cover each opening of the waterproof cover. Position between each of the waveguides Further, a correction unit for delaying the phase of the radio wave incident on each waveguide is provided.
[0009]
With this configuration, when the radio waves transmitted from a plurality of adjacent satellites are reflected by the reflecting mirror and enter the opening of each waveguide, the phase of the radio waves passing through the waterproof cover is Provided in a position that crosses between each waveguide Since it is delayed by the correction unit, it is possible to adjust so that the radiation pattern of the radio wave incident on each waveguide is reflected by the common part of the reflecting mirror, and the required reflecting mirror can be miniaturized. In addition, it is possible to reduce the manufacturing cost by using a waveguide with the same structure as that for one satellite, and it is only necessary to change the waterproof cover according to the separation angle of the satellite to be received. A high satellite broadcast receiving converter can be realized.
[0011]
the above In the configuration described above, as a specific configuration of the correction unit, a thick portion in which the thickness of the waterproof cover is partially increased, or a wall portion protruding from the back surface of the waterproof cover can be employed.
[0012]
DETAILED DESCRIPTION OF THE INVENTION
FIG. 1 is a cross-sectional view of a satellite broadcast receiving converter according to an embodiment, and FIG. 2 is a cross-sectional view of the satellite broadcast receiving converter as viewed from another direction. 3 is a perspective view of the waveguide, FIG. 4 is a front view of the waveguide, FIG. 5 is a perspective view of the dielectric feeder, FIG. 6 is a front view of the dielectric feeder, and FIG. 7 is an exploded view of the dielectric feeder. 8 is an explanatory view showing a state where the dielectric feeder is attached to the waveguide, FIG. 9 is an explanatory view showing the difference between the two dielectric feeders, and FIG. 10 is an exploded view of the shield case, the circuit board and the short cap. 11 is a rear view of the shield case, FIG. 12 is an explanatory view showing a state in which the circuit board is attached to the shield case, FIG. 13 is a sectional view taken along the line AA in FIG. 12, and FIG. The figure which shows the component mounting surface of a 1st circuit board 5 is an explanatory view showing the positional relationship between the phase conversion portion of the dielectric feeder and the minute radiation pattern, FIG. 16 is a cross-sectional view showing the mounting state of the waveguide, the circuit board, and the short cap, and FIG. 17 is the correction portion of the waterproof cover. FIG. 18 is a diagram illustrating a modification of the correction unit, FIG. 19 is a block diagram of the converter circuit, FIG. 20 is a diagram illustrating a layout state of circuit components, and FIG. It is explanatory drawing which expands and shows the junction part of a circuit board.
[0013]
The satellite broadcast receiving converter according to the present embodiment includes first and second waveguides 1 and 2 and first and second dielectric feeders held at the distal ends of the waveguides 1 and 2, respectively. 3 and 4, the shield case 5, the first and second circuit boards 6 and 7 attached inside the shield case 5, and a pair of shorts for closing the rear opening ends of the respective waveguides 1 and 2. The cap 8 and the waterproof cover 9 that covers these components are used.
[0014]
As shown in FIGS. 3 and 4, the first waveguide 1 is formed by winding and joining metal flat plates in a cylindrical shape, and fixing the joined portions with a plurality of caulking portions 1a. The distance between them is set to about ¼ wavelength of the guide wavelength λg. The first waveguide 1 has a substantially circular cross-sectional shape, and four parallel portions 1b are formed on the circumferential surface thereof at intervals of approximately 90 degrees in the circumferential direction. Each parallel portion 1b extends in a longitudinal direction parallel to the central axis of the first waveguide 1, and a snap claw 1c is extended at each rear end. A stopper claw 1 d is formed in the middle of the two parallel portions 1 b facing each other, and these stopper claw 1 d protrudes into the first waveguide 1. The second waveguide 2 is configured exactly the same as the first waveguide 1, and a duplicate description is omitted here, but it has a caulking portion 2a, a parallel portion 2b, a snap claw 2c, and a stopper claw 2d. is doing.
[0015]
Both the first dielectric feeder 3 and the second dielectric feeder 4 are made of a synthetic resin material having a low dielectric loss tangent. In the case of this embodiment, in consideration of the price, polyethylene (dielectric constant ε≈ 2.25) is used. As shown in FIG. 5 to FIG. 7, the first dielectric feeder 3 includes a first divided body 3 a having a radiating portion 10, and an impedance conversion section 11 and a phase conversion section 12 as a second divided body 3 b. It is configured. The radiating portion 10 has a conical shape extending in a trumpet shape, and a circular through hole 10a is formed at the center thereof. A fitting convex portion 10b is provided on the inner peripheral surface of the through hole 10a, and the first divided body 3a is opened with the fitting convex portion 10b as a parting line during injection molding. An annular groove 10c is formed on the end face of the radiating portion 10 and the depth of the annular groove 10c is set to about ¼ wavelength of the radio wave wavelength λ propagating through the annular portion.
[0016]
The impedance conversion unit 11 has a pair of curved surfaces 11a that narrow in an arc shape toward the phase conversion unit 12, and the cross-sectional shape of these curved surfaces 11a is an approximate quadratic curve. The end face of the impedance converter 11 is substantially circular, but four flat mounting surfaces 11b are formed at the periphery of the impedance converter 11 with an interval of approximately 90 degrees. In addition, a cylindrical protrusion 13 is provided at the center of the end face of the impedance converter 11, and a fitting recess 13 a is formed on the outer peripheral surface of the protrusion 13. Then, when the protrusion 13 is inserted into the through hole 10a and the end surface of the impedance converting portion 11 is abutted against the rear end surface of the radiating portion 10, the fitting concave portion 13a and the fitting convex portion 10b are snap-coupled inside the through hole 10a. Thus, the first divided body 3a and the second divided body 3b are integrated.
[0017]
At that time, if the length from the rear end surface of the radiating portion 10 to the fitting convex portion 10b is A and the length from the end surface of the impedance converting portion 11 to the fitting concave portion 13a is B, the A size is slightly larger than the B size. It is set to be long. For this reason, when the fitting recess 13a and the fitting projection 10b are snap-coupled, a force in a direction in which the rear end surface of the radiating unit 10 is pressed against the end surface of the impedance conversion unit 11 is generated, and the first divided body 3a and The second divided body 3b is integrated without backlash. An annular groove 13b is also formed on the tip surface of the protrusion 13, and when the first divided body 3a and the second divided body 3b are integrated, the both annular grooves 10c and 13b are arranged concentrically. The
[0018]
The phase conversion unit 12 is continuous with the tapered portion of the impedance conversion unit 11 and functions as a 90-degree phase shifter that converts circularly polarized light that has entered the first dielectric feeder 3 into linearly polarized light. The phase conversion unit 12 is a plate-like member having a substantially uniform thickness, and a plurality of notches 12a are formed at the tip thereof. The depth of each notch 12a is set to about ¼ wavelength of the in-tube wavelength λg, and the end surface of the phase converter 12 and the bottom surface of the notch 12a are two reflecting surfaces orthogonal to the traveling direction of the radio wave. It has become. Long grooves 12 b are formed on both side surfaces of the phase conversion unit 12.
[0019]
As shown in FIG. 8, the first dielectric feeder 3 configured in this manner is held by the first waveguide 1, and the radiating portion 10 of the first divided body 3a and the second divided body 3b. The protrusion 13 protrudes from the opening end of the first waveguide 1, and the impedance conversion unit 11 and the phase conversion unit 12 of the second divided body 3 b are inserted and fixed inside the first waveguide 1. At that time, each mounting surface 11b of the impedance converter 11 is press-fitted into the corresponding four parallel parts 1b with respect to the four parallel parts 1b formed on the inner peripheral surface of the first waveguide 1, and phase conversion is performed. The second divided body 3b can be easily attached to the first waveguide 1 with high positional accuracy by press-fitting both side surfaces of the portion 12 into the two parallel portions 1b opposed to each other by 180 degrees. Further, the stopper claws 1d formed on the two parallel portions 1b bite into the long grooves 12b of the phase converting portion 12 so that the second divided body 3b can be reliably prevented from coming out of the first waveguide 1. It has become.
[0020]
The second dielectric feeder 4 includes a first divided body 4a having a radiating portion 14, and an impedance conversion section 15 and a phase conversion section 16 as a second divided body 4b. The first divided body The basic configuration of inserting and fixing the protrusion 17 of the second divided body 4b in the through hole 14a of 4a is the same as that of the first dielectric feeder 3, but the following two points are the first dielectric feeder 3. Is different. The first difference is that the lengths of both phase converters 12 and 16 are changed. The length L1 of the phase converter 12 of the first dielectric feeder 3 and the phase of the second dielectric feeder 4 are the same. When the length L2 of the conversion unit 16 is compared, the relationship of L1> L2 is set. The second difference is that the colors of both the second divided bodies 3b and 4b are changed. For example, the second divided body 3b of the first dielectric feeder 3 is injection molded with the color of the raw material, The second divided body 4b of the second dielectric feeder 4 is injection molded by coloring the raw material red or blue.
[0021]
That is, among the constituent parts of the first dielectric feeder 3 and the second dielectric feeder 4, both the first divided bodies 3a and 4a are common parts, and both the second divided bodies 3b and 4b. Are different parts that have different lengths and colors of the phase converters 12 and 16. The reason why the lengths of both phase converters 12 and 16 are changed will be described later. When the colors of both second divided bodies 3b and 4b are changed, as shown in FIG. 9, the first and second dielectric feeders are used. By visually observing the colors of the protrusions 13 and 17 exposed on the end surfaces of the first divided bodies 3a and 4a when the 3 and 4 are held in the corresponding first and second waveguides 1 and 2, respectively. Thus, it is possible to easily and surely check for erroneous insertion of both the second divided bodies 3b and 4b.
[0022]
As shown in FIGS. 10 to 13, the shield case 5 is formed by pressing a metal flat plate, and a pair of connectors 18 are attached to an inclined surface 5 a formed on one side thereof. The flat top plate of the shield case 5 is provided with a pair of through holes 19 and a plurality of through holes 20, and a plurality of support portions 21 are provided on the periphery of each circular through hole 19. It is bent at a right angle toward the outside. The top plate of the shield case 5 is formed with a plurality of crosspieces 5 b surrounded by the through holes 20, and a plurality of locking claws 22 are perpendicular to the outside of the crosspieces 5 b toward the inside of the shield case 5. It is bent and formed. Furthermore, a plurality of recesses 23 are formed on the back surface of the crosspiece 5 b of the shield case 5, and these recesses 23 are formed in an elongated shape along the outer edge of the through hole 20.
[0023]
The first circuit board 6 is made of a material such as fluororesin-based polytetrafluoroethylene having a low dielectric constant and low dielectric loss, and its outer shape is formed larger than that of the second circuit board 7, and a plurality of appropriate parts are provided at appropriate positions. Through-hole 6a is provided. The second circuit board 7 is made of a material having a lower Q value than the first circuit board 6 such as glass-filled epoxy resin, and has one through hole 7a. In addition, ground patterns 24 and 25 are respectively provided on one side of the first and second circuit boards 6 and 7, and these ground patterns 24 and 25 are shield cases using solder 26 filled in the respective recesses 23. 5 is soldered. In this case, the cream solder is filled in the recesses 23 in advance, and the ground patterns 24 and 25 of the circuit boards 6 and 7 are superimposed on the back surface of the top plate of the shield case 5, and then the cream solder is put in a reflow furnace or the like. If melted, both circuit boards 6 and 7 can be grounded to the shield case 5 easily and reliably. At that time, as shown in FIGS. 12 and 13, if a part of each recess 23 is exposed to the outside of the outer edge portions of the circuit boards 6 and 7, it is possible to easily check visually for defects such as insufficient solder. It is possible to easily replenish the shortage of solder.
[0024]
The first and second circuit boards 6 and 7 are not only soldered to the shield case 5 but also locked to the back surface of the shield case 5 using the respective locking claws 22. In this case, after inserting the through holes 6 a and 7 a of both circuit boards 6 and 7 into the respective locking claws 22 of the shield case 5, these locking claws 22 are bent to the plate surface side of the first circuit board 6. In this case, both circuit boards 6 and 7 can be locked to the shield case 5. In particular, when looking at the first circuit board 6 that is larger than the second circuit board 7, appropriate portions including the center part and the peripheral part are pressed against the back of the top plate of the shield case 5 by the plurality of locking claws 22. Therefore, the warp of the first circuit board 6 can be reliably corrected.
[0025]
As shown in FIGS. 14 and 15, a pair of circular holes 27 are formed in the first circuit board 6, and the first to third bridging portions 27 a to 27 c are respectively formed in the circular holes 27. Is formed. In a state where the first circuit board 6 is fixed inside the shield case 5, the circular holes 27 coincide with the through holes 19 of the shield case 5. The first bridging portion 27a and the second bridging portion 27b intersect at an angle of approximately 90 degrees, and the third bridging portion 27c is in relation to the first and second bridging portions 27a and 27b. It intersects at an angle of approximately 45 degrees. However, the bridge portions 27 a to 27 c on the left side of the drawing and the bridge portions 27 a to 27 c on the right side of the drawing are in a line-symmetrical position with respect to a straight line P passing through the center of the first circuit board 6. The side opposite to the ground pattern 24 of the first circuit board 6 is a component mounting surface, and an annular ground pattern 28 is formed around the circular holes 27 on this component mounting surface. These ground patterns 28 are electrically connected to the ground pattern 24 through through holes, and four mounting holes 29 are formed in each ground pattern 28 at intervals of approximately 90 degrees in the circumferential direction. . Each attachment hole 29 is formed in a rectangular shape, and the four attachment holes 29 on the left side in the drawing and the four attachment holes 29 on the right side in the drawing are also in a line symmetrical position with respect to the straight line P.
[0026]
In addition, on the component mounting surface of the first circuit board 6, the pair of first probes 30 a and 30 b located on both the first bridging portions 27 a and the second bridging portion 27 b are located. A pair of second probes 31a and 31b and a pair of minute radiation patterns 32a and 32b located on both third bridging portions 27c are respectively formed in a pattern. Therefore, each pair of the first probe 30a, 30b, the second probe 31a, 31b, and the minute radiation patterns 32a, 32b on both left and right sides is also in a line-symmetrical position with respect to the straight line P. In the following description, in FIG. The minute radiation pattern 32a on the right side of the figure is called a first minute radiation pattern, and the minute radiation pattern 32b on the left side of the figure is called a second minute radiation pattern.
[0027]
The short cap 8 is formed by pressing a metal flat plate, and as shown in FIG. 10, a flange 8a is formed on the open end side of the bottomed shape. Four attachment holes 33 are formed in the flange portion 8a at intervals of approximately 90 degrees in the circumferential direction, and each attachment hole 33 is formed in a rectangular shape. The short cap 8 functions as a terminal surface that closes the rear opening ends of the waveguides 1 and 2, and as shown in FIG. 15, the short cap 8 and the first and second waveguides 1 and 2 are separated from each other. The first circuit board 6 is integrated. That is, the snap claws 1c and 2c of the first and second waveguides 1 and 2 protrude through the mounting holes 29 of the first circuit board 6 and protrude to the back surface side, and these snap claws 1c and 2c. The first circuit board 6 is sandwiched and fixed between the waveguides 1 and 2 and the pair of short caps 8 by snapping in the mounting holes 33 of the short cap 8. At that time, cream solder is applied in advance on the ground pattern 28 of the first circuit board 6, and the solder is melted in a reflow furnace after snap-in of the short cap 8, whereby the short cap 8 becomes the first circuit. Soldered to the ground pattern 28 of the substrate 6.
[0028]
Further, as described above, the first circuit board 6 is fixed inside the shield case 5, and each of the first waveguide 1 and the second waveguide 2 is connected to the first circuit board 6. In addition to being fixed vertically, the first circuit board 6 is inserted through the through hole 19 of the shield case 5 and protrudes to the outside. In this case, both the waveguides 1 and 2 are in contact with the respective support portions 21 formed on the peripheral edge of the through hole 19, and the support portions 21 cause undesired deformations such as the inclination of the both waveguides 1 and 2. Is prevented. In addition, the opening of the shield case 5 on the opposite side to the projecting direction of both the waveguides 1 and 2 is covered with a cover (not shown).
[0029]
Returning to FIGS. 1 and 2, the parts such as the two waveguides 1, 2, the dielectric feeders 3, 4, and the shield case 5 are housed inside the waterproof cover 9, and the pair of connectors 18 are waterproof covers. It protrudes from 9 to the outside. The waterproof cover 9 is made of a dielectric material having excellent weather resistance, such as polypropylene and ASA resin, and the radiating portions 10 and 14 of both the dielectric feeders 3 and 4 are opposed to the front surface portion 9 a of the waterproof cover 9. A pair of projecting walls 34 is provided substantially at the center of the front face portion 9a, and both projecting walls 34 extend so as to cross between the first and second waveguides 1 and 2. These projecting walls 34 function as a correction unit. Since the phase of the radio wave passing through the waterproof cover 9 is delayed by the projecting wall 34, the radiation pattern of the radio waves incident on both the waveguides 1 and 2 is changed to the volume of the projecting wall 34. Correction can be made according to the ratio. Therefore, as shown in FIG. 17, the radiation pattern can be corrected from a broken line shape (in the case where there is no protruding wall 34) to a solid line shape, and a miniaturized reflecting mirror (dish) can be used. In addition, as shown in FIG. 18, the thick part 35 which thickened the approximate center of the front-surface part 9a of the waterproof cover 9 can also be made into a correction | amendment part.
[0030]
The satellite broadcast receiving converter according to the present embodiment receives radio waves transmitted from two adjacent satellites (first satellite S1 and second satellite S2) launched into the sky. The second and second satellites S1 and S2 respectively transmit left-handed and right-handed circularly polarized signals. These circularly polarized signals are converged by a reflecting mirror, and then pass through the waterproof cover 9 to pass through the first and second satellites. Are input into the waveguides 1 and 2. For example, left-handed and right-handed circularly polarized signals transmitted from the first satellite S1 enter the inside of the first dielectric feeder 3 from the end surfaces of the radiating portion 10 and the protrusion 13, and the first dielectric feeder. 3 is propagated from the radiating unit 10 to the phase converting unit 12 through the impedance converting unit 11 and then converted into linearly polarized waves by the phase converting unit 12 and enters the first waveguide 1. That is, the circularly polarized wave is a polarized wave in which the combined vector of two linearly polarized waves having the same amplitude and a phase difference of 90 degrees is rotating, so that the circularly polarized wave propagates through the phase converter 12. Phases shifted by 90 degrees become in-phase, for example, left-hand circular polarization is converted into vertical polarization, and right-hand circular polarization is converted into horizontal polarization.
[0031]
At that time, since the plurality of annular grooves 10c and 13b having a depth of about λ / 4 wavelength are formed on the end face of the first dielectric feeder 3, the end face of the radiating portion 10 and the bottom faces of the annular grooves 10c and 13b are formed. The phase of the radio wave reflected at is reversed and canceled, and the reflection component of the radio wave toward the end face of the radiating unit 10 is greatly reduced. In addition, since the radiating portion 10 has a trumpet shape extending from the front opening end of the first waveguide 1, the radio wave can be efficiently converged in the first dielectric feeder 3, and the radiating portion. 10 axial lengths can be shortened.
[0032]
In addition, an impedance conversion unit 11 is provided between the radiation unit 10 and the phase conversion unit 12 of the first dielectric feeder 3, and the cross-sectional shape of the pair of curved surfaces 11 a formed on the impedance conversion unit 11 is approximately two. Since the first dielectric feeder 3 is converged so that the thickness of the first dielectric feeder 3 gradually decreases from the radiating unit 10 toward the phase converting unit 12 by being continuous with the following curve, the radio wave propagating in the first dielectric feeder 3 In addition, the phase difference with respect to the linearly polarized wave increases even if the length from the impedance converter 11 to the phase converter 12 is shortened. The total length of the first dielectric feeder 3 can be significantly shortened.
[0033]
Further, since the notch 12a having a depth of about λg / 4 wavelength is formed on the end face of the phase converter 12, the phase of the radio wave reflected by the bottom face of the notch 12a and the end face of the phase converter 12 is reversed and canceled. Thus, impedance mismatch at the end face of the phase converter 12 can also be eliminated.
[0034]
The left-handed and right-handed circularly polarized signals transmitted from the first satellite S1 are converted into vertical and horizontal polarized signals by the phase converter 12 of the first dielectric feeder 3 in this way, The first polarized wave is detected by the first probe 30a and the horizontal polarized wave is detected by the second probe 31a. Similarly, the left-handed and right-handed circularly polarized signals transmitted from the second satellite S2 enter the second dielectric feeder 4 from the end surfaces of the radiating portion 14 and the protrusion 17, and the second dielectric The phase conversion unit 16 of the feeder 4 converts left-handed circularly polarized light into vertical polarized light and right-handed circularly polarized light into horizontal polarized light. These vertically polarized waves and horizontally polarized waves travel in the second waveguide 1 toward the short cap 8, the vertically polarized waves are detected by the first probe 30b, and the horizontally polarized waves are detected by the second probe. Detected by 31b.
[0035]
Here, first and second minute radiation patterns 32a and 32b are formed on the first circuit board 6, and the first minute radiation pattern 32a corresponds to each axis of the first and second probes 30a and 31a. And the second minute radiation pattern 32b also intersects the axes of the first and second probes 30b and 31b at an angle of approximately 45 degrees. Disturbances in the electric fields of the vertical polarization and the horizontal polarization in the wave tubes 1 and 2 are suppressed by the first and second minute radiation patterns 32a and 32b, respectively, so that the isolation between the vertical polarization and the horizontal polarization is achieved. It is secured. The first and second minute radiation patterns 32a and 32b are asymmetric rectangles with respect to the axes of the probes 30a, 31a, 30b, and 31b, and their sizes (areas) are set to be relatively small. Reflection at the first and second minute radiation patterns 32a and 32b can be reduced while ensuring isolation between the polarization and the horizontal polarization.
[0036]
However, since the first and second minute radiation patterns 32a and 32b are in a line-symmetrical position with respect to the straight line P on the first circuit board 6, as is apparent from FIG. The second minute radiation pattern 32 b is substantially parallel to the phase converter 16 of the second dielectric feeder 4, and is substantially orthogonal to the phase converter 12 of the first dielectric feeder 3. In this case, the first minute radiation pattern 32a is substantially orthogonal to the phase conversion unit 12 as compared with the electric field distribution in the second waveguide 2 where the second minute radiation pattern 32b is substantially parallel to the phase conversion unit 16. Since the electric field distribution in the first waveguide 1 is deteriorated, the deterioration of the electric field distribution is corrected by increasing the dimension of the phase converter 12 in the axial direction. That is, as described above, the length L1 of the phase conversion unit 12 of the first dielectric feeder 3 and the length L2 of the phase conversion unit 16 of the second dielectric feeder 4 are set in a relationship of L1> L2. (See FIG. 9), and the phase conversion unit 12 is made long so that a phase shift does not occur in the linearly polarized wave traveling in the first waveguide 1.
[0037]
The reception signals detected by the first probes 30a and 30b and the second probes 31a and 31b are frequency-converted into IF frequency signals by converter circuits mounted on the first and second circuit boards 6 and 7. Is output. As shown in FIG. 19, the converter circuit receives a satellite broadcast signal transmitted from the first satellite S1 and the second satellite S2, and inputs the satellite broadcast signal input terminal 100 for deriving the satellite broadcast signal to a subsequent circuit. Received signal amplifier circuit 101 that amplifies and outputs the received satellite broadcast signal, filter unit 102 that attenuates the image frequency band of the input satellite broadcast signal, and frequency conversion of the satellite broadcast signal output from filter unit 102 The frequency converter 103 that performs the amplification, the intermediate frequency amplifier circuit 104 that amplifies the signal output from the frequency converter 103, and the signal selection means 105 that selects and outputs the satellite broadcast signal amplified by the intermediate frequency amplifier circuit 104. And the first and second regulators 1 for supplying a power supply voltage to each circuit unit such as the reception signal amplification circuit unit 101, the filter unit 102, and the signal selection unit 105. Has the 6,107 and the like.
[0038]
From the first satellite S1 and the second satellite S2, satellite broadcast signals of 12.2 GHz to 12.7 GHz with left-handed and right-handed circular polarization are transmitted, respectively, and these satellite broadcast signals are reflected from the reflector of the outdoor antenna device. Are converged and input to the satellite broadcast signal input end 100. The satellite broadcast signal input end 100 is transmitted from the first and second probes 30a and 31a for detecting the left and right circularly polarized signals transmitted from the first satellite S1, and from the second satellite S2. First and second probes 30b and 31b for detecting left-handed and right-handed circularly polarized signals are provided. As described above, the left-handed and right-handed circularly polarized signals transmitted from the first satellite S1 are converted into vertically polarized waves and horizontally polarized waves and detected by the first and second probes 30a and 31a, respectively. The first probe 30a outputs a left-hand circularly polarized signal SL1, and the second probe 31a outputs a right-hand circularly polarized signal SR1. On the other hand, the left-handed and right-handed circularly polarized waves transmitted from the second satellite S2 are converted into vertically polarized waves and horizontally polarized waves and detected by the first and second probes 30b and 31b, respectively. 30b outputs a left circularly polarized signal SL2, and the second probe 31b outputs a right circularly polarized signal SR2.
[0039]
The reception signal amplifier circuit unit 101 includes first to fourth amplifiers 101a, 101b, 101c, and 101d. The first amplifier 101a is a right-hand circularly polarized signal SR1, the second amplifier 101b is a left-handed circularly polarized signal SL1, the third amplifier 101c is a left-handed circularly polarized signal SL2, and the fourth amplifier 101d is right. Each of the circularly polarized wave signals SR2 is input, amplified to a predetermined level, and output to the filter unit 102.
[0040]
The filter unit 102 includes first to fourth band hermitate filters 102a, 102b, 102c, and 102d. The first and fourth band Hermitate filters 102a and 102d attenuate the frequency band of 9.8 GHz to 10.3 GHz which is the image frequency band of the first intermediate frequency signal FIL1 and the fourth intermediate frequency signal FIL2, The second and third band hermitate filters 102b and 102c attenuate the frequency band of 16.0 GHz to 16.5 GHz, which is the image frequency band of the second intermediate frequency signal FIH1 and the third intermediate frequency signal FIH2. The right-handed circularly polarized signal SR1 is the first band-eliminated filter 102a, the left-handed circularly-polarized signal SL1 is the second band-eliminated filter 102b, and the left-handed circularly-polarized signal SL2 is the third band-eliminated filter. The right-handed circularly polarized wave signal SR2 passes through the filter 102c and passes through the fourth band-eliminated filter 102d, and then is derived to the frequency converter 103.
[0041]
The frequency conversion unit 103 includes first to fourth mixers 103a, 103b, 103c, and 103d, a first oscillator 108, and a second oscillator 109. The first oscillator 108 (oscillation frequency = 11.25 GHz) is connected to the first mixer 103a and the fourth mixer 103d, and the satellite broadcast signal output from the first band Hermitate filter 102a is The first mixer 103a converts the frequency to the first intermediate frequency signal FIL1 of 950 MHz to 1450 MHz, and the satellite broadcast signal output from the fourth band Hermitate filter 102d is 950 MHz to 1450 MHz in the fourth mixer 103d. The frequency is converted to the fourth intermediate frequency signal FIL2. In addition, the second oscillator 109 (oscillation frequency = 14.35 GHz) is connected to the second mixer 103b and the third mixer 103c, and the satellite broadcast output from the second band aluminate filter 102b. The signal is frequency-converted to a second intermediate frequency signal FIH1 of 1650 MHz to 2150 MHz in the second mixer 103b, and the satellite broadcast signal output from the third band Hermitate filter 102c is 1650 MHz to 2650 MHz in the third mixer 103c. The frequency is converted to a third intermediate frequency signal FIH2 of 2150 MHz.
[0042]
The intermediate frequency amplification circuit unit 104 includes first to fourth intermediate frequency amplifiers 104a, 104b, 104c, and 104d, and inputs the first to fourth intermediate frequency signals output from the frequency conversion unit 103. This is amplified to a predetermined level and output to the signal selection means 105. That is, the first intermediate frequency signal FIL1 is sent to the first intermediate frequency amplifier 104a, the second intermediate frequency signal FIH1 is sent to the second intermediate amplifier 104b, and the third intermediate frequency signal FIH2 is sent to the third intermediate frequency amplifier 104c. In addition, the fourth intermediate frequency signal FIL2 is input to the fourth intermediate frequency amplifier 104d, and the output signals thereof are led to the signal selection means 105.
[0043]
The signal selection unit 105 includes first and second 110 and 111 and a signal switching control circuit 112. The first signal synthesis circuit 110 synthesizes the input first intermediate frequency signal FIL1 and the second intermediate frequency signal FIH1 and derives them to the signal switching control circuit 112. Similarly, the second signal synthesis circuit 111 synthesizes the inputted third intermediate frequency signal FIH 2 and the fourth intermediate frequency signal FIL 1 and derives them to the signal switching control signal 112. The signal switching control circuit 112 includes any one of a synthesized signal of the first intermediate frequency signal FIL1 and the second intermediate frequency signal FIH1, and a synthesized signal of the third intermediate frequency signal FIH2 and the fourth intermediate frequency signal FIL2. One of them is selected and output to the first output terminal 105a and the second output terminal 105b, respectively. This switching control will be described later.
[0044]
Separate satellite broadcast receiving televisions (not shown) are connected to the first and second output terminals 105a and 105b, respectively, and signal selecting means 105 is connected to each of the satellite broadcast receiving televisions. A voltage for operating each circuit unit is supplied together with a control signal to be controlled. For example, by superimposing a 22 kHz control signal on a direct current voltage of 15 V, it is discriminated whether to select a composite signal of intermediate frequency signals FIL1 and FIH1 or a composite signal of intermediate frequency signals FIL2 and FIH2. That is, the satellite broadcast receiving television receives the right-handed circularly polarized signal SR1 and the left-handed circularly polarized signal SL1 transmitted from the first satellite S1, and the right-handed clockwise signal transmitted from the second satellite S2. When selecting the case of receiving the circularly polarized signal SR2 and the left-handed circularly polarized signal SL2, control signals to be superimposed on the supply voltage are supplied to the output terminals 105a and 105b, respectively. These voltages are input from the first output terminal 105a to the signal switching control circuit 112 via the high-frequency blocking choke coil 113, and similarly from the second output terminal 105b to the high-frequency blocking choke coil 114. The signal is input to the signal switching control circuit 112.
[0045]
On the other hand, the first voltage and the second voltage are input to the first and second regulators 106 and 107 via the high-frequency blocking choke coils 113 and 114, respectively. A power supply voltage (for example, 8V) is supplied to each circuit unit. Therefore, the first and second regulators 106 and 107 have the same configuration, and a voltage stabilization circuit is configured by the integrated circuit. The output terminals of the first and second regulators 106 and 107 are connected to the power supply voltage output terminal 117 via backflow prevention diodes 115 and 116, respectively. Therefore, even when only one of the satellite broadcast receiving televisions is operating, the power supply voltage is supplied to each circuit unit. Further, since the first and second output terminals 105a and 105b are connected to the power supply voltage output terminal 117 via the regulators 106 and 107, respectively, the element isolation of the first and second regulators 106 and 107 is provided. For example, the control signal supplied from the first output terminal 105 a is not input to the signal switching control circuit 112. Similarly, the control signal supplied from the second output terminal 105 b is not input to the signal switching control circuit 112.
[0046]
As shown in FIG. 20, in the converter circuit configured in this way, the RF circuit components preceding the frequency conversion unit 103 are mounted on the first circuit board 6 and the intermediate frequency amplification circuit unit 104. The later-stage IF circuit components are mounted on the second circuit board 7, and the first circuit board 6 and the second circuit board 7 are partially overlapped and joined and integrated. Yes.
[0047]
In this case, the signal lines of the right-handed circularly polarized signals SR1 and SR2 of the first satellite S1 and the second satellite S2 are disposed on the outermost side of the first circuit board 6, and the first satellite S1 and the second satellite S2 are disposed on the inner side thereof. The first and fourth mixers 103a in which the signal lines of the left-hand circularly polarized signals SL1 and SL2 of the second satellite S2 are respectively laid out and the outer right-hand circularly polarized signals SR1 and SR2 are connected to the first oscillator 108. , 103d converts the frequency into first and fourth intermediate frequency signals FIL1 and FIL2 of 950 MHz to 1450 MHz, and connects the left-handed circularly polarized signals SL1 and SL2 to the second oscillator 109. The mixers 103b and 103c perform frequency conversion into second and third intermediate frequency signals FIH1 and FIH2 of 1650 MHz to 2150 MHz. That is, the first oscillator 108 and the second oscillator 109 are arranged in the central portion of the first circuit board 6, and the first oscillator 108 is connected to the outer first mixer 103 a via the oscillation signal line 36. It is connected to the fourth mixer 103d, and the second oscillator 109 is connected to the inner second mixer 103b and the third mixer 103c via the oscillation signal line 37.
[0048]
As shown in FIG. 21, the intermediate frequency signal lines 38 of the intermediate frequency signals FIL1, FIL2, FIH1, and FIH2 output from the mixers 103a to 103d on the first circuit board 6 are respectively connected via connection pins 39. It is connected to the intermediate frequency amplification circuit unit 104 on the second circuit board 7, and a ground formed on the first circuit board 6 in the overlapping portion of the first circuit board 6 and the second circuit board 7. The pattern 24 and the ground pattern 25a formed on the component mounting surface of the second circuit board 7 are in contact with each other. In addition, a derived pattern 40 is formed on the second circuit board 7 so as to face the ground pattern 25a. These derived patterns 40 are connected to the intermediate frequency amplifier circuit section 104 of the second circuit board 7 through the through holes 41. Both ends of the connection pin 39 are soldered to the intermediate frequency signal line 38 and the lead-out pattern 40. Therefore, the oscillation signal line 36 for connecting the first oscillator 108 to the first and fourth mixers 103a and 103d on the outside, and the intermediate frequency signals FIL1 to FIL4 from the mixers 103a to 103d are connected to the intermediate frequency amplifier circuit section. The intermediate frequency signal line 38 led to 104 can be crossed at the overlapping portion of the first circuit board 6 and the second circuit board 7 while having the ground.
[0049]
According to the satellite broadcast receiving converter according to the above-described embodiment, the first and second waveguides 1 and 2 having the respective axes arranged in parallel to each other are housed in the waterproof cover 9, and both waveguides are received. Since the front wall portion 9a of the waterproof cover 9 facing the radiating portions 10 and 14 of the dielectric feeders 3 and 4 held by the tubes 1 and 2 is provided with the protruding wall 34 or the thick portion 35 as the correcting portion, they are adjacent to each other. When the radio waves transmitted from the first and second satellites S1 and S2 are converged by the reflecting mirror and enter the inside of each of the waveguides 1 and 2, the phase of the radio wave passing through the waterproof cover 9 is corrected by a correction unit (protrusion). It can be delayed by the wall 34 or the thick part 35). For this reason, it can adjust so that the radiation pattern of the electromagnetic wave which injects into each waveguide 1, 2 may be reflected in the common part of a reflective mirror, and a required reflective mirror can be reduced in size.
[0050]
Moreover, since the same structure as the single waveguide used for the converter for receiving one satellite broadcast can be used as the first and second waveguides 1 and 2 as they are, an expensive die casting mold is used. Manufacturing cost can be reduced, and it is only necessary to change the waterproof cover 9 in accordance with the separation angle of the satellite to be received, thereby realizing a highly versatile satellite broadcast receiving converter. Can do.
[0051]
In the above embodiment, the first and second waveguides 1 and 2 hold the dielectric feeders 3 and 4, respectively, and radio waves passing through the waterproof cover 9 are emitted from the radiating portions of the dielectric feeders 3 and 4. Although the waveguide structure incident on 10 and 14 has been described, it is also possible to use a waveguide having a horn portion at one end.
[0052]
【The invention's effect】
The present invention is implemented in the form as described above, and has the following effects.
[0053]
Cover a plurality of waveguides with their axes parallel to each other with a waterproof cover, and this waterproof cover Position across each waveguide Since a correction unit that delays the phase of the radio wave incident on each waveguide is provided, when the radio wave transmitted from a plurality of adjacent satellites is reflected by the reflecting mirror and enters the opening of each waveguide, it is waterproof. By delaying the phase of the radio wave that passes through the cover with the correction unit, the radiation pattern of the radio wave incident on each waveguide can be adjusted to be reflected by the common part of the reflector, and the required reflector is downsized. can do. In addition, it is possible to reduce the manufacturing cost by using a waveguide with the same structure as that for one satellite, and it is only necessary to change the waterproof cover according to the separation angle of the satellite to be received. A high satellite broadcast receiving converter can be realized.
[Brief description of the drawings]
FIG. 1 is a sectional view of a satellite broadcast receiving converter according to an embodiment.
FIG. 2 is a cross-sectional view of the satellite broadcast receiving converter as viewed from another direction.
FIG. 3 is a perspective view of a waveguide.
FIG. 4 is a front view of a waveguide.
FIG. 5 is a perspective view of a dielectric feeder.
FIG. 6 is a front view of a dielectric feeder.
FIG. 7 is an explanatory view showing the dielectric feeder in an exploded manner.
FIG. 8 is an explanatory diagram showing a state in which a dielectric feeder is attached to a waveguide.
FIG. 9 is an explanatory diagram showing a difference between two dielectric feeders.
FIG. 10 is an exploded perspective view showing a shield case, a circuit board, and a short cap.
FIG. 11 is a rear view of the shield case.
FIG. 12 is an explanatory view showing a state in which the circuit board is attached to the shield case.
13 is a cross-sectional view taken along line AA in FIG.
FIG. 14 is a diagram showing a component mounting surface of the first circuit board.
FIG. 15 is an explanatory diagram showing a positional relationship between a phase converter of a dielectric feeder and a minute radiation pattern.
FIG. 16 is a cross-sectional view showing a state in which a waveguide, a circuit board, and a short cap are attached.
FIG. 17 is an explanatory diagram showing a relationship between a correction portion of a waterproof cover and a radiation pattern.
FIG. 18 is an explanatory diagram showing a modification of the correction unit.
FIG. 19 is a block diagram of a converter circuit.
FIG. 20 is an explanatory diagram showing a layout state of circuit components.
FIG. 21 is an explanatory view showing an enlarged joint portion of two circuit boards.
[Explanation of symbols]
1 First waveguide
2 Second waveguide
1a, 2a Caulking part
1b, 2b Parallel part
1c, 2c Snap claw
1d, 2d stopper claw
3 First dielectric feeder
4 Second dielectric feeder
3a, 4a First divided body
3b, 4b second divided body
5 Shield case
5b Pier
6 First circuit board
6a Through hole
7 Second circuit board
8 Short cap
9 Waterproof cover
10,14 Radiation part
10a Through hole
10b Mating convex part
10c annular groove
11, 15 Impedance converter
12, 16 Phase converter
13, 17 protrusion
13a Fitting recess
19 Through hole
20 Through-hole
21 Supporting part
22 Claw
23 recess
24, 25 Ground pattern
25a Ground pattern
26 Solder
27 circular holes
28 Earth pattern
29 Mounting hole
30a, 30b first probe
31a, 31b Second probe
32a First minute radiation pattern
32b Second minute radiation pattern
34 Projection wall
35 Thick part
36 Oscillation signal line
38 Intermediate frequency signal line
39 Connection pin
40 Derived patterns
41 Through hole
103 Frequency converter
103a, 103b, 103c, 103d First to fourth mixers
104 Intermediate frequency amplifier circuit
104a, 104b, 104c, 104d First to fourth intermediate frequency amplifiers
108 First oscillator
109 Second oscillator
S1 First satellite
S2 Second satellite

Claims (3)

Opposed to a reflecting mirror that reflects radio waves transmitted from a plurality of adjacent satellites, each of which is arranged so as to cover a plurality of waveguides whose axes are parallel to each other and the openings of these waveguides. A satellite broadcast comprising: a waterproof cover made of a dielectric; and a correction unit that delays a phase of a radio wave incident on each waveguide at a position across the waveguides of the waterproof cover. Receive converter. 2. The satellite broadcast receiving converter according to claim 1 , wherein the correction unit is a thick portion in which the thickness of the waterproof cover is partially increased. 2. The satellite broadcast receiving converter according to claim 1 , wherein the correction unit includes a wall portion protruding from the back surface of the waterproof cover.

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