JP3987211B2 - Mobile satellite broadcasting receiver - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a satellite broadcasting receiver for a mobile body that is mounted on a mobile body such as a vehicle and receives radio waves from a broadcasting satellite.
[0002]
[Prior art]
In a satellite broadcast receiving apparatus mounted on a moving body such as an automobile, it is necessary to configure the antenna to be lightweight, small and thin. For this reason, it is difficult to increase the gain over a wide range, and it is necessary to increase the gain only in a specific direction and receive weak satellite broadcast waves. When a moving body such as a vehicle moves, the direction of the directional beam of the antenna may deviate from the direction of the broadcasting satellite. For example, Japanese Patent Laid-Open No. 5-218729 discloses a prior art regarding an antenna that performs communication between one terrestrial satellite and the like. In this prior art, a rotary planar antenna is formed as a microstrip patch antenna. In a broadcast satellite receiver mounted on a vehicle, the antenna is tracked in the direction of the broadcast satellite with the azimuth angle of the antenna, and the elevation angle of the antenna is fixed. If the moving range of a moving body such as a vehicle is relatively narrow, broadcast satellite radio waves can be sufficiently received even if the elevation angle is fixed and only tracking in the azimuth direction is performed. However, when the moving range of the moving body becomes wide and moves throughout Japan, the gain for receiving satellite broadcast radio waves is insufficient with the fixed elevation angle, and reception is impossible.
[0003]
In Japanese Patent Laid-Open No. 9-214234, a plurality of satellite broadcast receiving antennas are mounted on a vehicle, a mechanism for tracking each receiving antenna in the azimuth direction is provided, and the elevation angle of the directional beam is fixed by each receiving antenna. The idea of expanding the beam width is proposed. It is also conceivable to perform control for tracking the elevation angle as well as tracking the azimuth angle. Furthermore, it is conceivable to prepare a plurality of antenna elements having different elevation angles and replace them depending on the region where the vehicle travels.
[0004]
[Problems to be solved by the invention]
Tracking the elevation angle of satellite broadcast reception antennas as the vehicle travels requires a mechanism to adjust the azimuth and elevation angles to the antenna, making it difficult to meet the requirements of being lightweight, small and thin It becomes. As suggested in Japanese Patent Laid-Open No. 9-214234, in the method of switching a plurality of antennas having different elevation angles, although the individual antennas are light, small and thin, the overall weight increases and the size is increased. End up.
[0005]
In a system in which a plurality of antenna elements having different elevation angles are prepared and exchanged by designating a region, it is necessary to remove and replace the antenna element of the antenna incorporated as a satellite broadcast receiver. Although it is necessary to use a screw or the like so that the antenna element can be replaced, it is very difficult for a general user to perform work while keeping the torque of the screw within an appropriate range. If the torque is insufficient, the attached antenna element may come off during movement. If the torque is excessive, tightening bolts or the like may be damaged during use, and the antenna element may be detached from the satellite broadcast receiver. In order to fully manage the tightening torque of the screw and replace the antenna element, it is necessary to ask an automobile dealer or service factory to replace the antenna element while paying careful attention to torque management. .
[0006]
There is also known an antenna that can obtain the same effect as setting the elevation angle for each region by moving one array antenna element from the center axis of rotation without replacing the array antenna element. Yes. Even if such an antenna is not automatically adjustable, the labor required for the adjustment will be the same as that for the above-described replacement.
[0007]
SUMMARY OF THE INVENTION An object of the present invention is to provide a movable body that can be formed into a small, lightweight and thin antenna, and can easily and reliably adjust the elevation angle of the antenna element in the direction of the broadcasting satellite even when moving over a wide range. It is to provide a satellite broadcast receiving apparatus.
[0008]
[Means for Solving the Problems]
  The present invention is a mobileA support part set on top;
  A rotating part installed rotatably with respect to the support part;
  An antenna element that is supported by the rotating part and receives satellite broadcast;
  SaidRotating partSaidAntenna element directivity beeIsAn azimuth tracking mechanism that angularly shifts to track a broadcast satellite;
  An elevation angle adjusting mechanism including a pushing member whose tip is in contact with the antenna element on the surface of the rotating part, and a drive mechanism for driving the pushing member;
  A positioning mechanism for positioning the rotating unit at a predetermined rotation reference position;
  In a state where the rotating unit is positioned at the rotation reference position by the positioning mechanism, the elevation angle adjustment mechanism displaces the relative position of the antenna element with respect to the rotating unit, thereby increasing the elevation angle of the directional beam of the antenna element. When adjusting and rotating the rotating part by the azimuth tracking mechanism, the push-out member is retracted from the surface of the rotating part by the driving mechanism.This is a mobile satellite broadcast receiver characterized by the above.
[0009]
  According to the present invention, rotationPartThe supported antenna element has a rotating part so that the azimuth angle of the directional beam tracks the broadcast satellite.WhoIt is angularly displaced by the position angle tracking mechanism. The elevation angle of the directional beam of the antenna element can be adjusted by the relative displacement of the antenna element with respect to the rotating part.PredictDeciderotationIt can be positioned by a positioning mechanism so as to be a reference position, and can be adjusted by an elevation angle adjusting mechanism. The elevation adjustment mechanism,Rotating partButPositioned by the positioning mechanismStatestateso,The pushing member is driven by the drive mechanism, the pushing member is brought into contact with the antenna element and pressed, and the antenna element is relatively moved with respect to the rotating portion.Displace,The elevation angle can be adjusted. The elevation angle is adjusted by positioning the rotating part with the positioning mechanism.rotationSince the positioning is performed at the reference position, usually the rotating part is angularly displaced by the azimuth tracking mechanism to track the azimuth in the direction of the broadcasting satellite, and the elevation angle can be adjusted as necessary. By directing the direction of the directional beam toward the direction of the broadcasting satellite, it is possible to efficiently receive weak satellite broadcasting radio waves.Further, when a broadcasting satellite is tracked by angularly displacing the rotating part by the azimuth tracking mechanism, the pushing member of the elevation angle adjusting mechanism is driven by the driving mechanism and retracted from the surface of the rotating part.The antenna element only needs to have the necessary sensitivity in the direction of the directional beam, and can be made small, thin, and lightweight as a whole.
[0010]
  In the present invention, the elevation angle adjusting mechanism is provided on both sides that are symmetrical with respect to the axis of the rotating portion.RuIt is characterized by that.
[0011]
  According to the present invention, the elevation angle adjusting mechanism is located at a position that is symmetrical with respect to the rotation axis of the rotating unit on both sides of the rotating unit.ButProvidedIsTherefore, the displacement of both directions can be simultaneously performed by the displacement of only the extrusion, and the elevation angle can be adjusted quickly.
[0012]
  In the present invention, the elevation angle adjusting mechanism is provided at one place facing the periphery of the rotating portion.,
  in frontThe positioning mechanism isSaidFor the elevation adjustment mechanismSaidRotating partPhasePositioning is possible at two reference positions having different azimuth angles of 180 ° from each other.
[0013]
According to the present invention, the elevation angle adjusting mechanism is provided in one place, and after positioning by the positioning mechanism to adjust the displacement of the antenna element with respect to the rotating portion, if necessary, the 180 ° rotating portion is angularly displaced, and 180 ° The antenna element can be displaced relative to the rotating portion in the direction opposite to that before the angular displacement of °.
[0014]
  In the present invention, the elevation angle adjusting mechanism isThe base end of the pushing member opposite to the portion in contact with the antenna element is set as a pushing standard.Spring biased in the direction of positionIncluding,
  The drive mechanism isThe extruded memberExtrusion standardBased on position,Of the directional beamSet according to elevation angleMoveamountMove in response toIt is characterized by that.
[0015]
  According to the present invention, PushThe base end of the projecting member with a springExtrusion standardEnergize in the position direction,Extrusion standardIt can be reliably returned to the position.Drive mechanism is extrusion standardExtrusion amount set corresponding to the elevation angle with reference to the positionDesperationTo projectThe extruded memberBecause it drivesExtrusion standardAs long as the position is accurate, the antenna element can be displaced with an accurate pushing amount.
[0016]
  In the present invention, the elevation angle adjusting mechanism isThe extruded memberAntenna elementWhenContactOn the base end side opposite to the portion to beExtruded memberIncluding a wall member provided at an extrusion reference position of,
  The drive mechanism moves the push member in accordance with a movement amount set corresponding to the elevation angle of the directional beam with the push reference position as a reference, and after adjusting the elevation angle of the directional beam The push member is moved until the base end of the push member contacts the wall member.It is characterized by that.
[0017]
  According to the present invention, PushOn the base end side of the projecting member,Standard for extrusionExtrusion standardWall member in positionButEstablishmentIsThe The drive mechanism is an extruded memberExtrusion standardAdjust the elevation angle of the antenna element by projecting the push amount set corresponding to the elevation angle with respect to the position, and after adjustment, return the push member more than the push amount and bring the base end into contact with the wall member ,certainlyExtrusion standardThe position can be secured.
[0018]
  In the present invention, the elevation angle adjusting mechanism isThe extruded memberAntenna elementWhenContactIncluding a conductive member provided at an extrusion reference position of the extrusion member on the base end side opposite to the portion to be
  The drive mechanism moves the push member in accordance with a movement amount set corresponding to the elevation angle of the directional beam with the push reference position as a reference, and after adjusting the elevation angle of the directional beam The push member is moved until the base end of the push member contacts the conductive member.It is characterized by that.
[0019]
  According to the present inventionAAntenna elementThe back ofAfter adjusting the angle, the extruded member becomes the reference for extrusion on the proximal sideExtrusion standardpositionSet inThe drive member is driven to return to contact until the contact is electrically detected.Extrusion standardTo the correct position, and the next time you adjust the elevation,Extrusion standardSince the position can be used as a reference, the adjusted elevation angle can also be set accurately.
[0020]
Further, the present invention provides an optical sensor at a position on the rotating unit where a directional beam having a predetermined elevation angle is obtained for the antenna element,
The elevation angle adjusting mechanism identifies a moving position of the antenna element based on an output of an optical sensor.
[0021]
According to the present invention, an optical sensor is provided at a position where a predetermined elevation angle is obtained when the antenna element is displaced on the rotating part. Since the displacement of the antenna element is identified based on the output of the optical sensor, the displacement of the moving position of the antenna element is corrected based on the output of the optical sensor based on mechanical assembly error, etc. The position can be adjusted so that the elevation angle can be obtained.
[0022]
The present invention is characterized in that a mechanical switch is provided instead of the optical sensor.
[0023]
According to the present invention, it is possible to identify that the antenna element is in a position where an appropriate elevation angle can be obtained on the rotating unit using a mechanical switch.
[0024]
Further, in the present invention, there are a plurality of positions where the directional beam having the predetermined elevation angle can be obtained, and an optical sensor is provided at each position.
The elevation angle adjustment mechanism operates only an optical sensor provided at a corresponding position according to an elevation angle to be adjusted.
[0025]
According to the present invention, an optical sensor is provided at a position corresponding to a plurality of elevation angles, and only the optical sensor corresponding to the elevation angle to be adjusted is driven to adjust the elevation angle. It is possible to reliably adjust the two elevation angles.
[0026]
Further, in the present invention, the elevation angle adjusting mechanism is characterized in that when the antenna element is displaced relative to the rotating portion, the driving force at the start of the displacement is increased and the driving force is decreased before the end of the displacement. To do.
[0027]
According to the present invention, when the antenna element is displaced relative to the rotating part, the driving force at the start of the displacement is strengthened, so that the antenna element is mechanically restrained at a position corresponding to the zero point position or a specific elevation angle. Even in the locked state, the movement can be started with a strong driving force. Since the driving force is weakened before the end of the displacement, it can be surely stopped at a predetermined position.
[0028]
  The present invention also provides the above-mentionedThe mechanical switch
  SaidAntenna elementIs at a position on the rotating part where the directional beam having the predetermined elevation angle is obtained.1st when in a state and in another positionState ofstateAnd differentSecondState ofState andRukoAnd features.
[0029]
  According to the present invention,mechanicalBy providing a switch mechanism, it is possible to easily identify the antenna element with different conduction states depending on whether the antenna element is in a position corresponding to the elevation angle or not.
[0030]
In the present invention, the elevation angle adjusting mechanism can select a design value and a value before and after the design value as a displacement amount of the antenna element corresponding to the elevation angle to be adjusted with respect to the rotating portion. And
[0031]
According to the present invention, the design value and the values before and after it can be selected as the position where the antenna element is displaced relative to the rotating part, so that the moving position differs from the set value due to manufacturing errors or the like. However, the antenna element can be stopped at a position where an appropriate elevation angle can be obtained by selecting front and rear values.
[0032]
In the present invention, the elevation angle adjusting mechanism can check whether the antenna element is correctly displaced by comparing before and after the displacement.
[0033]
According to the present invention, it is possible to confirm whether or not the antenna element is correctly performed by comparing the displacement of the antenna element before and after the displacement. Therefore, if it is confirmed that the antenna element is correctly displaced, the elevation angle is set to a predetermined value. It can be reliably adjusted to take a value.
[0034]
Further, in the present invention, the elevation angle adjusting mechanism can move the antenna element to a position corresponding to a plurality of elevation angles, and the antenna element can be directly moved from a position corresponding to one elevation angle to a position corresponding to another elevation angle. It is characterized by moving.
[0035]
According to the present invention, since the antenna element is directly moved from a position corresponding to one elevation angle to a position corresponding to another elevation angle, the elevation angle can be switched in a short time.
[0036]
In the present invention, the elevation angle adjusting mechanism can move the antenna element to a position corresponding to a plurality of elevation angles, and the antenna element is moved from a position corresponding to one elevation angle to a position corresponding to another elevation angle. When moving, the antenna element is once moved to a position corresponding to the elevation angle closest to one side and then moved to a position corresponding to the other elevation angle.
[0037]
According to the present invention, when switching from one elevation angle to another elevation angle, the antenna element is moved to a position corresponding to the elevation angle closest to one side and then moved to a position corresponding to the other elevation angle. Even if there is an error in the value of the elevation angle, it can be accurately adjusted to another elevation angle.
[0038]
According to the present invention, the elevation angle adjusting mechanism moves the antenna element at a relatively low speed in the vicinity of the position corresponding to the elevation angle and at a relatively high speed in other portions.
[0039]
According to the present invention, since the antenna element is moved at a relatively low speed in the vicinity of the position corresponding to the elevation angle, the adjustment can be made accurately when the elevation element is adjusted to the elevation angle. Since the antenna element is moved at a relatively high speed at other positions, the time required for adjustment can be shortened.
[0040]
  Further, in the present invention, the positioning mechanism is provided with reflective optical sensors at positions on both sides that are symmetrical with respect to the axis, facing the periphery of the rotating portion,
  In the rotating part,rotationA reflection adjusting unit is provided at a position facing the reflective optical sensor when positioned at the reference position so that the reflection state differs from other positions.
[0041]
  According to the present invention, as the positioning mechanism, reflection type optical sensors are provided at positions on both sides symmetrical to the axis, facing the periphery of the rotating part,rotationCorresponding to the reference position, a reflection adjustment unit having a reflection state different from other positions is provided at a position facing the reflective optical sensor.rotationThe reference position can be easily detected.
[0042]
  Further, in the present invention, the positioning mechanism is provided with a reflective optical sensor in one place facing the periphery of the rotating part,
  In the rotating part,rotationA reflection adjustment unit is provided at a position facing the reflective optical sensor when positioned at the reference position so that the reflection state is different from other positions,
  When the antenna element needs to be displaced in the opposite direction after the antenna element is pushed and displaced in one direction at the positioned position, the elevation angle adjusting mechanism displaces the rotating part by 180 °. Then, the antenna element is pushed and displaced in the one direction.
[0043]
  According to the present invention, as the positioning mechanism, a reflective optical sensor is provided at one location facing the periphery of the rotating part,rotationSince the reflection adjusting portion is provided at the position facing the reflective optical sensor when positioned at the reference position so that the reflection state is different from other positions, positioning at one place can be easily performed. When positioned, push the antenna element in one direction to adjust the elevation angle, and when it is necessary to displace the antenna element in the reverse direction, move the rotating part 180 ° and push the antenna element in the same direction. And the elevation angle can be adjusted.
[0044]
Further, the present invention is characterized in that a mechanical switch is used in place of the combination of the reflective optical sensor and the reflection adjusting unit.
[0045]
According to the present invention, positioning can be accurately performed using a mechanical switch.
[0046]
The present invention also includes a stop detection device that detects whether or not the moving body is stopped,
The elevation angle adjusting mechanism performs the elevation angle adjustment when it is detected by the stop detection device that the moving body is stopped.
[0047]
According to the present invention, the elevation angle adjustment is performed when the stop detection device detects that the moving body is stopped. Therefore, the elevation angle can be accurately adjusted without being affected by the movement of the moving body.
[0048]
The present invention also includes a flatness detecting device for detecting whether or not the place where the moving body is present is flat,
The elevation angle adjusting mechanism performs the elevation angle adjustment when it is detected by a flatness detecting device that the moving body is present in a flat place.
[0049]
According to the present invention, the elevation angle is adjusted when the flatness detecting device detects that the place where the moving body exists is flat, so that the elevation angle is accurately adjusted without being influenced by the inclination of the moving body. can do.
[0050]
Further, the present invention provides a display unit that displays which reception area corresponds to the elevation angle of the antenna element adjusted by the elevation angle adjustment mechanism,
It further includes an input unit that can specify a reception area by a user operation, and a control unit that controls the elevation angle adjustment mechanism so that the elevation angle of the antenna element is switched to an elevation angle corresponding to the reception area specified by the input unit. It is characterized by that.
[0051]
According to the present invention, the display unit displays which reception area the elevation angle corresponds to, and the input unit can specify the reception area by a user operation, and the elevation angle corresponding to the reception area specified by the input unit Since the control unit controls the elevation angle adjustment mechanism so as to switch to, the user can automatically adjust the elevation angle only by selecting an appropriate reception area while looking at the display unit.
[0052]
According to the present invention, the control unit detects the reception level of satellite broadcasting before and after switching of the reception area, and notifies the user on the display unit when the reception level decreases due to switching.
[0053]
According to the present invention, when the reception area of the satellite broadcast is lowered by switching the reception area, the display section notifies the user, so that the user performs an operation such as returning the reception area to the input section. be able to.
[0054]
In the present invention, the control unit may switch to an elevation angle corresponding to a plurality of reception areas, calculate a satellite broadcast reception level, and select an elevation angle at which the reception level is highest.
[0055]
According to the present invention, it is possible to calculate the reception level of satellite broadcasting by switching to elevation angles corresponding to a plurality of reception areas, and to select the elevation angle at which the reception level is the highest. It can be performed.
[0056]
The present invention also includes a navigation device that detects the current position of the mobile body based on prestored map information,
The control unit detects the elevation angle switching timing based on a current position detected by a navigation device and map information.
[0057]
According to the present invention, since the control unit detects the elevation angle switching timing based on the current position of the moving body detected by the navigation device and the map information provided in the navigation device, it is appropriate for the movement of the moving body. Satellite broadcasting can be received at an elevation angle.
[0058]
The present invention also includes a terrestrial receiver that receives terrestrial broadcast radio waves at the current position of the mobile body,
The control unit detects an elevation angle switching timing based on a terrestrial broadcast station received by the terrestrial receiver.
[0059]
According to the present invention, the terrestrial receiver receives a terrestrial broadcast radio wave and detects the timing of elevation angle switching based on the received broadcast station. For example, an appropriate reception area from the area where the broadcast station exists The elevation angle can be switched by selecting.
[0060]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings. Note that portions corresponding to the matters described in advance are denoted by the same reference numerals, and redundant description is omitted.
[0061]
  FIG. 1 shows a schematic configuration of an antenna device 1 in a mobile satellite broadcast receiver as a first embodiment of the present invention. The fixed portion 2 is mounted on the roof of a vehicle that is a moving body, and serves as a basic support portion of the antenna device 1. The rotating unit 3 is rotationally driven from the fixed unit 2 and can be angularly displaced about a substantially vertical axis. An array antenna element 4 is provided on the rotating unit 3, and the azimuth angle direction of the directional beam is the rotating unit.3It is possible to track in the direction of satellite broadcasting by angular displacement by rotation of. Rotating part3The driving for the rotation can be performed by belt driving or gear driving as an azimuth tracking mechanism.
[0062]
The array antenna element 4 of the present embodiment can change the elevation angle and change the satellite broadcast reception area by a sliding operation that moves in the horizontal direction relative to the rotating unit 3. The elevation angle of the array antenna element 4 is changed in a state where the rotating unit 3 is positioned in a preset reference direction with respect to the fixed unit 2. The state in which the rotating unit 3 is positioned in the reference direction is detected by the photosensor 5. The photosensor 5 includes a light emitting unit 5a and a light receiving unit 5b, and is a reflection type that detects a position by a change in intensity received by the light receiving unit 5b by reflecting light emitted from the light emitting unit 5a. The photosensor 5 is provided in the fixed portion 2, and in a state where the rotating portion 3 is positioned at the reference position with respect to the fixed portion 2, light emitted from the light emitting portion 5 a of the photosensor 5 is a through-hole provided in the rotating portion 3. The reference position is detected so that the reflected light having a sufficient intensity is not received by the light receiving portion 5b. For the detection of the reference position, it is possible to adopt a configuration in which the reflection is small at a position other than the reference position and the reflection is large at the reference position, and a transmissive type photosensor can be used. Furthermore, the reference position can be detected by a mechanical switch.
[0063]
When the rotating unit 3 is positioned at the reference position with respect to the fixed unit 2, the moving motor 7 linearly drives the rack 8 with the pinion 9 to bring the tip of the rack 8 into contact with the array antenna element 4, and thereby the array antenna. The element 4 can be pushed with respect to the rotating unit 3 to perform a sliding operation for moving the relative position. The rack 8 is urged away from the array antenna element 4 by the spring 10, and when the base end side of the rack 8 comes into contact with the wall member 11 erected on the fixing portion 3, the rack 8 is at the reference position. Zero point positioning can be performed. When the moving motor 7 is driven to move the rack 8 to the array antenna element 4 side and the array antenna element 4 is pushed out, the relative position of the array antenna element 4 relative to the angular displacement axis of the rotating unit 3 is increased depending on the pushing position. The position is adjusted, and the elevation angle of the directional beam formed by the array antenna element 4 can be adjusted. The rotating unit 3 is rotationally driven by the rotating motor 12 with respect to the fixed unit 2, and can change the azimuth angle of the array antenna element 4 to track the direction of the broadcasting satellite. A guide mechanism is provided in order to reliably reciprocate the rack 8 in the radial direction passing through the rotation axis of the rotating unit 3.
[0064]
The moving motor 7 is preferably a stepping motor in consideration of accuracy and the like. Further, guides 13 and 14 are provided on the rotating unit 3 in order to guide the array antenna element 4. The moving positions are a plurality of positions corresponding to elevation angles set in advance for a plurality of areas, and are mechanically locked to slide lock mechanisms 15a, 15b, 15c, ..., 15m; 16a, 16b, 16c, ..., 16m is provided. The slide lock mechanisms 15a, 15b, 15c,..., 15m are in a positional relationship in which the array antenna element 4 generates a predetermined elevation angle with respect to the rotating portion 3 by, for example, a leaf spring. Sometimes mechanical restraining force is applied. In order to further change the locked position, it is necessary to generate a large torque that overcomes the restraining force of the lock motors 15a, 15b, 15c,..., 15m; 16a, 16b, 16c,. There is. The necessary torque of the moving motor 7 needs to be considered up to this point. Further, when the torque increases, it is necessary to use a plurality of pinions 9 in a stacked manner. Note that the torque is weakened when approaching the target position so as not to pass the lock position that is the target of the displacement.
[0065]
The rack 8 shown in FIG. 1 can only adjust the elevation angle by pushing the array antenna element 4 in one direction with respect to the rotating unit 3. In order to perform the adjustment in the reverse direction, the rotating unit 3 may be stopped by being angularly displaced by 180 degrees with respect to the fixed unit 2. Since the antenna adjustment mechanism of the moving motor 7 and the rack 8 is displaced only in the direction in which the array antenna element 4 is pushed out, it is installed on the fixed portion 2 side and the azimuth tracking is performed by rotating the rotating portion 3 by the rotating motor 12. In operation, the rack 8 can be returned to the zero point so that it does not become an obstacle. Further, the elevation angle adjusting mechanism can be similarly configured not only by the combination of the moving motor 7 and the rack 8, but also by using a linear stepping motor, a push-type solenoid, or the like.
[0066]
FIG. 2 shows a configuration necessary for the vehicle 20 equipped with the antenna device 1 of FIG. 1 to receive the satellite broadcast radio wave 22 from the broadcast satellite 21. The antenna device 1 is mounted on the roof of the vehicle 20 and has a directional beam 23 directed from the array antenna element 4 toward the broadcasting satellite 21. The directional beam 23 has a high gain range so that a weak satellite broadcast radio wave 22 can be received. The received satellite broadcast radio wave 22 is amplified by the receiving device 24 and the content of the broadcast is output. An angular displacement axis 25 for tracking the azimuth angle of the directional beam 23 in the direction of the broadcast satellite 21 is generally directed in the vertical direction, and the azimuth angle of the directional beam 23 is approximately in the horizontal plane. Varies with angular displacement. The tracking control device 26 performs control for tracking the azimuth angle of the directional beam 23 around the angular displacement axis 25 in the direction of the broadcasting satellite 21 so that the reception level of the satellite broadcast radio wave 22 output from the receiving device 24 is increased. . The elevation angle adjustment device 27 is used to adjust the elevation angle of the directional beam 23 as necessary. The tracking control device 26 and the elevation angle adjustment device 27 perform azimuth angle control and elevation angle adjustment by a program operation of the microcomputer device 28, respectively. The elevation angle adjustment is performed according to an operation input to the remote control device 29. The driver of the vehicle 20 operates the remote controller 29 when the area where the vehicle 20 travels is far away from the area where the elevation angle is initially set and the elevation angle needs to be newly adjusted. The adjustment device 27 can be operated to adjust the elevation angle of the directional beam 23.
[0067]
FIG. 3 shows a planar configuration of the array antenna element 4 of FIG. 1, and FIG. 4 shows a side sectional configuration of the array antenna element 4. The array antenna element 4 is a kind of planar antenna formed by arranging a plurality of microstrip antenna elements 31 to 3n on one surface of a generally disc-shaped radial waveguide 30. According to the arrangement of the microstrip antenna elements 31 to 3n on the surface of the radial waveguide 30, the directional beam 23 is formed in a specific direction. In the space in the radial waveguide 30, the tuner feed pin 40 installed at the position of the rotation axis of the rotating unit 3 protrudes from the back side facing the surface on which the microstrip antenna elements 31 to 3 n are provided. Yes. From each of the microstrip antenna elements 31 to 3n, antenna element feed pins 41 to 4n protrude into spaces in the radial waveguide 30 respectively. The radial waveguide 30 is guided by the guides 13 and 14 with respect to the rotating portion 3 and can be relatively displaced in the radial direction around the tuner power supply pin 40. Since the elevation angle θ of the directional beam 23 as the array antenna element 4 is determined by the relative position between the radial waveguide 30 and the rotating unit 3, the radial waveguide 30 is moved at adjustment positions corresponding to a plurality of regions. , 15m; 16a, 16b, 16c,..., 16m are provided so as to increase the resistance to.
[0068]
The rotating unit 3 is rotatably supported by the fixed unit 2 with a bearing 50. A gear 51 is fixed to the output shaft of the rotary motor 12 and rotationally drives an external gear 52 formed around the rotating unit 3. A rotation lock mechanism 53 that positions and locks the rotating portion 3 with respect to the fixed portion 2 at a reference position by the photosensor 5 is also provided.
[0069]
FIG. 5 shows the array antenna element 4 from the two microstrip antenna elements 3i and 3j out of the plurality of microstrip antenna elements 31 to 3n with respect to the tuner feed pin 40 protruding into the radial waveguide 30. The received signal is transmitted from the antenna element feed pins 4i and 4j. Each of the microstrip antenna elements 3 i and 3 j receives the satellite broadcast radio wave 22 coming from a direction inclined with respect to the surface of the radial waveguide 30 at a common elevation angle θ. At this time, there is a Pij stroke difference in the space outside the array antenna element 4 between the microstrip antenna elements 3i and 3j at different positions. That is, the phase surface of the satellite broadcast radio wave that has just reached one microstrip antenna element 3i reaches the other microstrip antenna element 3j after a further distance Pij. On the other hand, the received signal transmitted through the radial waveguide 30 from the antenna element feed pin 4i corresponding to the microstrip antenna element 3i to the tuner feed pin 40 needs to travel a distance Pi. On the other hand, the distance that the signal received by the microstrip antenna element 3j is transmitted through the radial waveguide 30 from the antenna element feed pin 4j to the tuner feed pin 40 is Pj.
[0070]
FIG. 6 shows a planar arrangement of the two microstrip antenna elements 3i and 3j shown in FIG. If the phase difference between the signals received by the two microstrip antenna elements 3i and 3j is Pij− (Pi−Pj) and the resulting phase difference is 0 or an integral multiple of 2φ, both microstrip antenna elements 3i, Since the signals received at 3j are added as they are, the gain increases. If it can arrange | position with such a phase difference with respect to several microstrip antenna elements 31-3n, the gain as a whole can be improved. Further, if the relative position between the radial waveguide 30 and the tuner feed pin 40 is changed, the elevation angle θ at which the gain is increased can be changed. That is, the elevation angle of the directional beam 23 can be changed.
[0071]
FIG. 7 shows an operation procedure for receiving satellite broadcasting in the antenna device 1 of the present embodiment. The change of the area by adjusting the elevation angle of the array antenna element 4 starts when the user gives an instruction from the remote control device 29 in step s1. At this time, in step s2, the current area setting can be displayed and confirmed on a monitor display screen provided in the receiving device 24 or the like. It is also possible to automatically determine the timing of area change, display it on the monitor, and inform the user.
[0072]
When an area change signal is received from the remote control device 29, for example, the monitor screen of the receiving device 24 displays whether or not the vehicle is “stopped at a flat place where it can be received”. to go into. Such a display is performed in order to perform the area changing operation safely and reliably. However, it is also possible to automatically detect the “stop state”, “is a flat place”, and start the operation. Further, whether or not the satellite broadcast radio wave 22 from the broadcast satellite 21 can be received can be easily determined based on the C / N detection voltage output from the receiving device 24, and so only when it cannot be received. It is also possible to simply give a warning such as “Please move to a flat place” to the user. Thereafter, although the user designates the change area, a warning may be given when an incorrect operation is performed. It is also possible to automatically select the optimum area at that point.
[0073]
In step s2, when the change area is first recognized as (1), the photosensor 5 is operated by the position detection circuit operation in (2), and the rotation unit 3 is aligned to the reference position with respect to the fixed unit 2. Move. In this operation, (3) a control for stopping the normal tracking operation and shifting to the low-speed rotation operation is performed. As a result, as shown in step s 3, the rotary motor 12 rotates at a low speed, and the rotating portion 3 is angularly displaced relative to the fixed portion 2.
[0074]
In step s10, the photo sensor 5 as the position detection circuit determines whether or not to detect a predetermined position. When the predetermined position is detected, it is confirmed that the rotation unit 3 is aligned with the fixed unit 2. When only one set of photosensors 5 is provided as shown in FIG. 1, the array antenna element 4 needs to be rotated 180 degrees depending on the elevation angle change direction corresponding to the area to be changed by pushing the rack 8 after alignment. . In step s11, it is determined whether it is necessary to rotate 180 degrees. When it is determined that it is necessary, the rotation unit 3 is rotated by 180 degrees in step s12. After the rotation of 180 degrees in step s12 or after determining that the rotation is not performed in 180 degrees in step s11, a rotation stop signal is sent from the photosensor 5 to the microcomputer device 28 in step s13.
[0075]
The 180 degree rotation is performed by rotating the rotating unit 3 by 180 degrees with the rotary motor 12 after positioning by the photosensor 5. Reflection type optical sensors for position detection such as the photo sensor 5 are arranged on both sides symmetrical with respect to the angular displacement axis 25, and the reflection adjusting unit such as the non-reflecting part of the rotating unit 3 is different in reflection state from other positions. If it is arrange | positioned, 180 degree rotation can be detected easily.
[0076]
Next, in step s20, the microcomputer device 28 stops the rotating unit 3 with respect to the fixed unit 2 in response to the rotation stop signal from the photosensor 5. A moving motor that operates the rack 8 by operating the rotation lock mechanism 53 to lock the positional relationship of the rotating unit 3 with respect to the fixed unit 2 in a state where the positioning of the rotating unit 3 and the fixed unit 2 is completed. Turn on 7 power. In step s21, the rotation of the rotary motor 12 is stopped by stopping the electric drive. Next, in step s22, the moving motor 7 is operated in the direction in which the rack 8 is pushed out. If the distance based on the instruction from the microcomputer device 28 is moved, in step s23, the array antenna element 4 is provided with the slide lock mechanisms 15a, 15b, 15c, ..., 15m; 16a, 16b, 16c, ..., 16m. Can be locked in position. Next, in step s24, the moving motor 7 is operated in the direction in which the rack 8 is returned, and when the base end of the rack 8 reaches a position just before contacting the wall 11, the power supply to the moving motor 7 is turned off in step s25. . In step s26, the rack 8 is urged to be pulled toward the wall 11 by the spring 10, so that even if the driving of the moving motor 7 is stopped, the rack 8 is mechanical until the proximal end abuts against the wall 11. To stop at the reference zero position.
[0077]
In the above description, the array antenna element 4 in which a plurality of microstrip antenna elements 31 to 3n are arranged on the radial waveguide 30 is used as the array antenna element, but other forms of planar antennas are similarly used. be able to.
[0078]
FIG. 8 shows a schematic configuration of an antenna device 61 according to the second embodiment of the present invention. In the present embodiment, the elevation angle adjusting mechanisms 62 and 63 including the moving motor 7, the rack 8, the pinion 9, the spring 10, and the wall member 11 are provided on both sides that are symmetrical with respect to the angular displacement axis 25 of the rotating unit 3. As a result, even if the elevation angle adjusting mechanisms 62 and 63 can be displaced only in the pushing direction with respect to the rotating portion 3 of the antenna element 4, they can be displaced in any direction, and the elevation angle can be adjusted quickly. Can be done.
[0079]
FIG. 9 shows the operation of the elevation angle adjusting device 27 in the embodiment of FIG. 1 or FIG. The operation is started from step a1, and in step a2, a reception area is designated by a user such as a vehicle driver using the remote control device 29 of FIG. The reception area is set to divide the whole country into a plurality of areas and include each area and a part of the adjacent area. Within one reception area, the elevation angle of the antenna element 4 is made constant, and the area is set so that satellite broadcast reception is possible without performing elevation angle tracking. In step a3, an elevation angle previously associated with the designated reception area is selected. In step a4, the pushing amount from the zero point position of the rack 8 necessary for the displacement of the antenna element 4 to obtain the selected elevation angle is selected. For the amount of extrusion, the design values corresponding to the elevation angles in a plurality of stages and the values before and after each design value are stored as data in a ROM or the like in the microcomputer device 28, taking into account assembly errors and the like. In order to select a value for obtaining an appropriate elevation angle, an adjustment is made.
[0080]
In step a5, the moving motor 7 is driven to push out the antenna element 4. A position where an appropriate elevation angle can be obtained is set as a lock position, and a mechanical switch such as an optical sensor or a limit switch similar to the reflection type photo sensor shown in FIG. 1 is provided. Make it reachable to reach. In addition, a so-called click stop mechanism may be provided so that the restraining force against the displacement of the antenna element 4 with respect to the rotating portion 3 is increased at the lock position. If it is determined in step a6 that the lock position has not been reached, the process returns to step a5 to continue the displacement. When the lock position is reached, it is determined in step a7 whether or not the displacement position corresponds to the elevation angle selected in step a3. When the lock position corresponds to another elevation angle, the process returns to step a5 to continue the displacement.
[0081]
When it is determined in step a7 that the position is displaced to the lock position corresponding to the selected elevation angle, a return amount for returning the rack 8 is set in step a8. The return amount is set to be larger than the extrusion amount selected in step a4. In step a9, the moving motor 7 is driven in the direction opposite to that in step a5, and the rack 8 is returned to the direction of the wall member 11. Since the return amount is larger than the extrusion amount, even when the base end of the rack 8 abuts against the wall member 11 and the movement of the rack 8 is mechanically stopped, the movement motor 7 is driven and the rack 8 is moved. It is possible to reliably return to the zero position. In step a10, the driving of the moving motor 7 is stopped and the operation is ended. If a stepping motor is used as the moving motor 7, it is possible to correspond to the number of pulses for driving the pushing amount, the returning amount, etc., so the number of pulses for driving the moving motor 7 is set from the time of pushing for causing the rack 8 to protrude. However, the number is increased when the rack 8 is returned.
[0082]
FIG. 10 shows a partial configuration of an elevation angle adjusting mechanism 65 as a third embodiment of the present invention. In the present embodiment, the rack 8 is formed of a conductive material such as metal, and the conductive member 66 is provided at the zero point position that is the reference position to which the rack 8 returns. The elevation angle adjusting device 67 can electrically detect that the base end of the rack 8 is in contact with the conductive member 66 and confirm the return of the rack 8 to the zero point position. The elevation angle adjusting device 67 can also detect electrical contact between the rack 8 and the array antenna element 4.
[0083]
FIG. 11 shows the operation of the elevation angle adjusting device 67 in the embodiment of FIG. The operations from step b1 to step b9 are the same as those from step a1 to step a9 in FIG. In step b10, it is determined whether or not the rack 8 has returned to the zero point position where the base end of the rack 8 contacts between the contact points 65 and 66. If the space between the rack 8 and the conductive member 66 is in an open state, the rack 8 has not returned to the zero point, and returns to step b7 to continue the movement of the rack. When an electrical short circuit between the rack 8 and the conductive member 66 is detected in step b8, it is confirmed that the rack 8 has returned to the zero point position, and the drive of the moving motor is stopped in step b11. End the operation. If the return amount is set to be larger than the extrusion amount in step b4 in step b8, the zero point return detection in step b10 should be performed at a time that is not a return corresponding to the entire return amount. .
[0084]
FIG. 12 shows an operation for confirming that an abnormality such as a step-out has not occurred while the rack 8 is pushed out and the array antenna element 4 is slid in the embodiment of FIG. The confirmation operation instruction is given to the elevation adjusting device 47 by operating, for example, the remote control device 29 of FIG. 10 while the rack 8 is at the zero point position. When an instruction is given, the operation from step c1 is started, and the moving motor 7 is driven in step c2 to push the rack 8 in the direction of the drive shaft of the rotating unit 3. In step c3, it is electrically determined whether or not the tip of the rack 8 starts to contact the peripheral edge of the array antenna element 4. If not, the process returns to step c2 and the extrusion of the rack 8 is continued. When the contact start is detected in step c3, the amount of movement from the zero point position to the contact is calculated in step c4. If the movement motor 7 is a stepping motor, the movement amount is represented by the number of driven pulses.
[0085]
In step c5, the moving motor 7 is driven in the reverse direction to return the rack 8 to the zero point position. The operation of returning to the zero point position is performed as shown in FIG. Next, in step c6, the movement amount calculated in step c4 is set as the extrusion amount. In step c7, the moving motor 7 is driven by the amount of extrusion. In step c8, it is determined whether or not the start of electrical contact is detected between the tip of the rack 8 and the array antenna element 4. If the start of contact is detected, it is confirmed that an abnormality such as step-out has not occurred, and it is determined normal in step c9 and the operation is terminated. If the contact has not yet started in step c8, it is determined that an abnormality such as step-out has occurred. Even after the contact has already started, it is determined that an abnormality such as a displacement has occurred. If abnormality is judged, abnormality display etc. will be performed in step c10, and operation | movement will be complete | finished.
[0086]
FIG. 13 shows a configuration related to elevation angle adjustment as a fourth embodiment of the present invention. The elevation angle adjusting device 68 of the present embodiment is arranged so that the position of the array antenna element 4 locked by the lock mechanisms 15a, 15b, 15c,... 15m; 16a, 16b, 16c,. Detected from outputs from 69c,. If the lock mechanisms 15a, 15b, 15c, ... 15m; 16a, 16b, 16c, ..., 16m are provided at positions where a desired elevation angle is actually obtained, the sliding distance of the array antenna element 4 by pushing out the rack 8 Even if there is an error between the design value and the actual distance after assembly as an antenna device, it can be displaced to a position where an accurate elevation angle can be obtained. When there are a plurality of lock positions, only the photosensors 69a, 69b, 69c,..., 69m corresponding to the target lock position are selectively operated to make it easy to understand the end point of the slide operation.
[0087]
FIG. 14 shows a schematic configuration of a switch 70 also serving as a mechanical lock mechanism as a fifth embodiment of the present invention. The contact member 71 is made of a spring metal material such as phosphor bronze into a leaf spring shape, and is attached to a position facing the guides 13 and 14 of the array antenna element 4. A through hole 72 is formed at a position where a desired elevation angle can be obtained. FIG. 14A shows a state in which the array antenna element 4 is positioned at the lock position, and FIG. 14B shows a state in which the array antenna element 4 slides between the lock positions. The contact member 71 is fitted into the through-hole 72 in the locked position, and no electrical contact with the guides 13 and 14 occurs. When deviating from the locked position, the contact member 71 contacts the guides 13 and 14. When a positive power supply voltage is applied to the contact member 71 through the resistor 73 and the guides 13 and 14 are grounded, a voltage change as shown in FIG. It is done. That is, since the voltage is high from time t1 to time t2, it can be seen that the lock position is as shown in FIG.
[0088]
The contact member 71 may be a roller. If the roller is urged toward the guides 13 and 14 with a spring, it can be used for detecting the lock position as in the case of the leaf spring-like contact member 71. When a roller is used, the frictional resistance between the guides 13 and 14 at the time of sliding becomes small, so that the elevation angle can be adjusted smoothly.
[0089]
FIG. 15 shows an operation as a sixth embodiment of the present invention. In the present embodiment, when the reception area is switched, the elevation angle adjustment mechanism pushes the array antenna element 4 once to the innermost lock position. That is, when the operation is started from step d1 and the reception area is designated from the remote control device 29 in step d2, the corresponding elevation angle is selected in step d3. In step d4, a lock position necessary for obtaining the selected elevation angle is selected. In step d5, the rotating unit 3 is positioned at the reference position, the rack 8 is pushed out, and the array antenna element 4 is pushed to the back. In FIG. 1, the position where the lock mechanisms 15m and 16m are provided is the position corresponding to the end receiving area.
[0090]
Next, in step d6, a movement amount necessary for movement from the innermost lock position to the lock position selected in step d4 is calculated and set. As shown in FIG. 1, when the extrusion can be performed only from one side, the rotating unit 3 is rotated 180 degrees, and then the moving motor 7 is driven in step d7. In step d8, it is determined whether or not the lock position has been reached. The drive of the moving motor 7 is continued until the lock position is reached. If so, the movement is terminated in step d9. If the elevation angle adjusting mechanisms 62 and 63 are provided on both sides as in the embodiment of FIG. 8, it is not necessary to rotate the rotating unit 3 180 degrees after step d6, and the array antenna element 4 is immediately reversed. Can slide in the direction.
[0091]
In the movement of the present embodiment, the array antenna element 4 is once moved to the innermost lock position and then moved to the target lock position. Therefore, the reset is performed every time with the innermost lock position as a reference. The same effect can be achieved and reliable movement can be performed. As long as each lock position can be electrically and electrically detected as in the embodiment of FIG. 13 and FIG. 14, any lock position can be used as a reference, but the elevation angle adjustment mechanism can only push out. , It is preferable that it can be pushed from any lock position to the deepest lock position.
[0092]
In order to shorten the movement time for changing the elevation angle, the movement speed other than the target lock position may be increased. However, in the case of passing a lock position other than the target in the middle of movement and mechanical lock mechanisms 15a, 15b, 15c,..., 15m; 16a, 16b, 16c,. It is necessary to increase the torque near the lock position to overcome the increase in resistance at the lock position.
[0093]
Further, it is possible to move the lock position directly in accordance with the switching of the reception area without moving the lock position to the deepest lock position. If it moves directly, the operation time can be shortened. However, since the movement amount is set based on the current lock position, if the current position is shifted for some reason, the switched lock position is also shifted. In the embodiment of FIG. 15, even if the current position is deviated, it can be moved to a new lock position without being affected by it.
[0094]
FIG. 16 shows a schematic system configuration of an in-vehicle satellite broadcast receiving device 76 as a seventh embodiment of the present invention. The elevation angle adjusting device 77 of the present embodiment is realized by the program operation of the microcomputer device 78 together with the tracking control device 26. The elevation angle adjustment device 77 can be given an instruction about the elevation angle adjustment operation from the remote control device 79. At this time, information such as the current reception area setting can be displayed on the display device 80 and given to the user. . The display device 80 is a monitor for displaying a satellite broadcast television image, and a liquid crystal display device (LCD) or the like is used.
[0095]
If the elevation angle of the array antenna element 4 is changed while the vehicle 20 is traveling, the azimuth angle is also changed due to the change in the traveling direction, and the elevation angle of the changed directional beam 23 is the satellite broadcast from the broadcasting satellite 21. It becomes difficult to confirm whether or not it is suitable for receiving the radio wave 22. In the present embodiment, a gyro sensor 81 or the like is provided so that the elevation angle corresponding to the change of the reception area can be switched while the vehicle 20 is stopped. Further, if the elevation angle is changed according to the change of the reception area at an inclined place, even if the elevation angle of the directional beam 23 with respect to the horizontal plane is adjusted, the direction of the actual satellite broadcast radio wave 22 does not match. For this reason, an inclinometer 82 or the like is provided so that the elevation angle can be switched after confirming that the place is flat. If the elevation angle is to be switched while the vehicle is stopped or not in a flat place, a warning may be displayed on the display device, or the elevation angle may not be switched unless the condition is satisfied. Since a user such as a driver of the vehicle 20 can directly determine whether the vehicle is stopped or on a flat ground, the gyro sensor 81 and the inclinometer 82 can be omitted.
[0096]
The operation of displaying the current reception area on the display device 80 is provided with a display key 83 on the remote control device 79, for example, so that it can be instructed by an operation on the display key 83. A user such as a driver can easily determine whether it is necessary to switch the reception area by comparing the displayed reception area with the area where the vehicle 20 is currently traveling. Further, while traveling near the boundary between adjacent reception areas, it is difficult to determine which reception area is more suitable for the elevation angle. For this reason, the C / N signal level obtained from the receiving device 24 is stored in the memory 84 in the microcomputer device 78 before the elevation angle is switched, and the C / N signal level obtained after the receiving area switching operation is switched. Be able to compare with the previous one. When the C / N signal level is lower after switching than before switching, the user can be notified by the display device 80 or the like to recognize that switching has resulted in an undesirable result.
[0097]
FIG. 17 shows an operation of automatically selecting an optimal reception area near the boundary of the reception area. The operation starts from step e1, and in step e2, the operation of the automatic selection function is instructed via the remote control device 79. In step e3, the process waits until a condition for switching such as when the vehicle is stopped or on flat ground is satisfied. If the condition is satisfied, the satellite broadcast radio wave 22 is received in step e4, and the C / N signal level in the current reception area is stored in the memory 84. In step e5, it is determined whether or not there is a reception area adjacent to the current reception area. For example, if there is a lock position adjacent to the lock position corresponding to the current reception area, the array antenna element 4 is moved to the lock position in step e6, and the reception area is switched. After switching the reception area, the process returns to step e4, and the C / N signal level for the reception area is stored in the memory 84. In the next step e5, it is determined whether or not there is a reception area in which the elevation angle change direction is adjacent to the original reception area in the reverse direction. When it is determined that there is, the switching to the reception area is further performed in step e6, and the process returns to step e4 to store the C / N signal level.
[0098]
If satellite broadcast waves are received and the C / N signal level is stored for the original reception area and all adjacent reception areas, it is determined in step e5 that there is no remaining adjacent reception area, and is stored in step e7. The C / N signal level of each receiving area is compared. In step e8, the reception area with the maximum C / N signal level is selected as the optimum area, the elevation angle is switched to match that reception area, and the operation ends in step e9.
[0099]
FIG. 18 shows a schematic electrical configuration of an in-vehicle satellite broadcast receiving device 86 as an eighth embodiment of the present invention. The elevation angle adjusting device 87 is realized by the microcomputer device 88 together with the tracking control device 26. In the present embodiment, the timing of exchange of the reception area is determined using the navigation device 90 that has a map database and detects the current position. The satellite broadcast receiving device 24 and the navigation device 90 use a common display device 80 as a monitor. When the current position approaches from the vicinity of the boundary with another reception area from within one reception area, the display device 80 is notified of exchange of the reception area, and if the user supports, an automatic selection operation as shown in FIG. Thus, the reception area is switched.
[0100]
FIG. 19 shows a schematic electrical configuration as a ninth embodiment of the present invention. In this embodiment, the tuner 91 receives radio and television broadcasts by terrestrial waves, acquires information about the area where the vehicle is traveling, and the elevation angle adjustment device 97 of the in-vehicle satellite broadcast reception device 96 adjusts the elevation angle. . The elevation angle adjusting device 97 is realized by the microcomputer device 98 together with the tracking control device 26. For example, if a broadcasting station that can receive a terrestrial broadcast is identified, the area in which the vehicle is traveling can be determined. If the area in which the vehicle is traveling is known, it can be determined whether or not the current reception area is appropriate, and switching to an appropriate reception area can be performed in the same manner as in the above-described embodiment.
[0101]
【The invention's effect】
  As described above, according to the present invention,, TimesWith the positioning mechanismrotationIn a state where it is positioned at the reference positionAThe elevation angle can be adjusted by moving the antenna element relative to the rotating part.. oneSince the elevation angle can be adjusted so as to correspond to a plurality of reception areas with one antenna element, the trouble of exchanging the antenna element or manually adjusting it can be saved.
  Further, when the broadcast satellite is tracked by angularly displacing the rotating part by the azimuth tracking mechanism, the pushing member can be retracted from the surface of the rotating part so that the angular displacement of the rotating part is not obstructed.
[0102]
  According to the invention, the antenna elementStrangeSince the position can be simultaneously performed by an elevation angle adjusting mechanism provided on both sides symmetrical with respect to the axis, the time required for the adjustment can be shortened.
[0103]
Further, according to the present invention, since an elevation angle adjustment mechanism that adjusts the elevation angle by pushing the antenna element on the rotating portion may be provided at one place, it is possible to reduce the size and weight.
[0104]
  According to the present invention, the pushing member is biased by a spring.Extrusion standardSince the position can be kept accurate,Standard for displacement of extruded memberIt is possible to prevent malfunction due to accumulation of position errors.
[0105]
  Also according to the invention,Extrusion standardA wall member is provided at the position to ensure that the push-out member is pulled back.Extrusion standardPositioning can be performed by contacting the position. by thisStandard for displacement of extruded memberIt is possible to prevent malfunction due to accumulation of position errors.
[0106]
  According to the present invention, the extruded member isExtrusion standardWhen you return to the position,Extrusion standardSince the contact with the conductive member provided at the position can be electrically detected,Standard for displacement of extruded memberIt is possible to prevent malfunction due to accumulation of position errors.
[0107]
Further, according to the present invention, the position at which the predetermined elevation angle can be obtained can be identified by the optical sensor, and therefore the elevation angle can be adjusted reliably by correcting the deviation of the mounting position during assembly. .
[0108]
According to the present invention, the position of the antenna element corresponding to a certain elevation angle can be recognized with a mechanical switch, and an accurate elevation angle can be set.
[0109]
Further, according to the present invention, when the position of the antenna element corresponding to the elevation angle is recognized by a plurality of optical sensors, only the optical sensor provided at the position corresponding to the elevation angle to be set is driven. Adjustments can be made.
[0110]
Further, according to the present invention, when the antenna element is moved with respect to the rotating part, the driving force at the start of the movement is strengthened, so even if a high-speed force is applied at a position corresponding to a specific elevation angle, the antenna element is surely The movement of the element can be started. Since the driving force is weakened before the movement is completed, the movement can be surely stopped in correspondence with the elevation angle to be adjusted.
[0111]
  Also according to the invention,mechanicalThe movement of the antenna element relative to the rotating portion can be adjusted so that the antenna element stops at a position corresponding to the elevation angle by an electrical output from the switch mechanism.
[0112]
Also, according to the present invention, even if the position where the antenna element should be stopped with respect to the elevation angle is different from the design value, the design value of the displacement amount of the antenna element and the values before and after the antenna element can be stopped at a more appropriate position. An appropriate position can be selected.
[0113]
Further, according to the present invention, it is possible to confirm whether or not the antenna element is correctly displaced by the elevation angle adjusting mechanism by comparing before and after the displacement, so it is confirmed whether or not the elevation angle adjustment is correctly performed. be able to.
[0114]
Further, according to the present invention, it is possible to quickly perform an operation of switching from one elevation angle to another elevation angle.
[0115]
Further, according to the present invention, since the operation of switching from one elevation angle to another elevation angle is performed after moving to the position corresponding to the elevation angle closest to the one side, it is ensured even if there is a deviation in the position of the original elevation angle. It is possible to switch to another elevation angle.
[0116]
Further, according to the present invention, the moving speed of the antenna element can be changed to reliably stop at the position corresponding to the elevation angle.
[0117]
  According to the invention, the optical sensor is provided on both sides symmetrical with respect to the axis, and the elevation angle is adjusted.rotationPositioning to the reference position can be performed reliably.
[0118]
Further, according to the present invention, the optical sensor is provided at one place, the antenna element is moved on the rotating part in one direction, the rotating part is further displaced by 180 °, and the other direction is adjusted. it can.
[0119]
In addition, according to the present invention, the rotating part can be reliably positioned with a mechanical switch.
[0120]
According to the present invention, the elevation angle can be adjusted while the moving body is stopped.
Further, according to the present invention, the elevation angle can be adjusted when the moving body is present on a flat place.
[0121]
In addition, according to the present invention, the reception area can be displayed on the display unit, and the user can perform an operation of designating the reception area on the input unit to switch the elevation angle corresponding to the reception area.
[0122]
Further, according to the present invention, when the reception area is switched and the reception level is lowered, the user can be notified, so that the user can perform an operation for returning the reception area.
[0123]
Further, according to the present invention, it is possible to automatically select the elevation angle at which the reception level is the highest.
[0124]
Moreover, according to this invention, an appropriate elevation angle can be selected based on the present position of the moving body which a navigation apparatus detects.
[0125]
Further, according to the present invention, it is possible to receive a terrestrial broadcast, confirm the reception area based on the broadcast station, detect the timing for switching the elevation angle, and switch the reception area appropriately.
[Brief description of the drawings]
FIG. 1 is a simplified plan view showing a schematic configuration of an antenna device 1 as a first embodiment of the present invention.
2 is a block diagram showing a schematic electrical configuration of a vehicle-mounted satellite broadcast receiving device using the antenna device of FIG. 1;
FIG. 3 is a plan view of the array antenna element 4 of FIG. 1;
4 is a side cross-sectional view of the array antenna element 4 of FIG. 1. FIG.
5 is a side cross-sectional view showing the relationship between the arrangement of two microstrip antenna elements 3i to 3j and the elevation angle of a directional beam in the array antenna element 4 of FIG. 1. FIG.
6 is a partial plan view showing a planar arrangement of two microstrip antenna elements 3i to 3j in FIG.
7 is a flowchart showing an operation procedure when performing elevation angle adjustment with the antenna device 1 of FIG. 1; FIG.
FIG. 8 is a simplified plan view showing a schematic configuration of an antenna device 61 according to a second embodiment of the present invention.
FIG. 9 is a flowchart showing an operation of the elevation angle adjusting device 27 in the embodiment of FIG. 1 or FIG.
FIG. 10 is a partial plan view showing a schematic configuration of an elevation angle adjusting mechanism 65 as a third embodiment of the invention.
11 is a flowchart showing the operation of the elevation angle adjusting device 67 in the embodiment of FIG.
12 is a flowchart showing an operation for confirming that an abnormality such as step-out has not occurred in the embodiment of FIG.
FIG. 13 is a partial block diagram showing an electrical configuration related to elevation angle adjustment as a fourth embodiment of the invention.
14 is a simplified cross-sectional view showing a schematic configuration of a switch 70 also serving as a mechanical lock mechanism and a time chart showing the operation thereof as a fifth embodiment of the present invention. FIG.
FIG. 15 is a flowchart showing an operation according to a sixth embodiment of the present invention.
FIG. 16 is a block diagram showing a schematic system configuration of an in-vehicle satellite broadcast receiving device as a seventh embodiment of the present invention.
FIG. 17 is a flowchart showing an operation of automatically selecting an optimal reception area near the boundary of the reception area in the embodiment of FIG.
FIG. 18 is a block diagram showing a schematic electrical configuration of an in-vehicle satellite broadcast receiving device 86 as an eighth embodiment of the present invention.
FIG. 19 is a block diagram showing a schematic electrical configuration of an in-vehicle satellite broadcast receiving device 96 as a ninth embodiment of the present invention.
[Explanation of symbols]
1 Antenna device
2 fixed part
3 Rotating part
4 Array antenna element
5 Photosensor
6 through holes
7 Moving motor
8 racks
9 Pinion
10 Spring
11 Wall
12 Rotating motor
13,14 guide
15a, 15b, 15c, ..., 15m; 16a, 16b, 16c, ..., 16m slide lock mechanism
20 vehicles
21 Broadcasting satellite
22 Satellite broadcasting radio waves
23 Directional beam
24 Receiver
25 Angular displacement axis
26 Tracking control device
27, 67, 77, 87, 97 Elevation angle adjustment device
28, 78, 88, 98 Microcomputer device
29,79 Remote control device
30 radial waveguide
31-3n microstrip antenna element
40 Tuner power supply pin
41-4n Antenna element feed pin
53 Rotation lock mechanism
62, 63, 65 Elevation angle adjustment mechanism
66 Conductive members
69a, 69b, 69c, ..., 69m Photosensor
70 switch
76, 86, 96 Vehicle-mounted satellite broadcast receiver
80 Display device
81 Gyro sensor
82 Inclinometer
83 Display key
90 Navigation device
91 Tuner

Claims (26)

A support part set on the moving body ;
A rotating part installed rotatably with respect to the support part;
An antenna element that is supported by the rotating part and receives satellite broadcast;
The rotating portion, and the azimuth angle tracking mechanisms directional beam of the antenna element is angularly displaced so as to track the broadcast satellite,
An elevation angle adjusting mechanism including a pushing member whose tip is in contact with the antenna element on the surface of the rotating part, and a drive mechanism for driving the pushing member;
A positioning mechanism for positioning the rotating unit at a predetermined rotation reference position;
In a state where the rotating unit is positioned at the rotation reference position by the positioning mechanism, the elevation angle adjustment mechanism displaces the relative position of the antenna element with respect to the rotating unit, thereby increasing the elevation angle of the directional beam of the antenna element. A mobile satellite broadcast receiving apparatus characterized in that, when adjusting, and rotating the rotating part by the azimuth tracking mechanism, the pushing mechanism retracts the pushing member from the surface of the rotating part . The elevation adjustment mechanism, the moving body satellite broadcast receiver according to claim 1, wherein the Ru provided on both sides which are symmetrical with respect to the axis of the rotating part. The elevation angle adjusting mechanism is provided at one location facing the periphery of the rotating part ,
Before Symbol positioning mechanism, movable body satellite according to claim 1, wherein the mutually 180 ° azimuth the rotating part with respect to the elevation angle adjusting mechanism are possible positioning in two different reference positions Broadcast receiving device. The elevation angle adjusting mechanism includes a spring that biases the base end of the pushing member opposite to the portion in contact with the antenna element in the pushing reference position direction,
The drive mechanism, said pusher member, based on the extrusion reference position, according to claim 1, wherein the moving in correspondence with the amount of movement is set to correspond to the elevation angle of the directional beam The satellite broadcast receiver for mobile objects according to any one of the above. The elevation angle adjusting mechanism, in the antenna element and the contact portion opposite the base end side of the pushing member includes a wall member provided in the extrusion reference position of the pusher member,
The drive mechanism moves the push member in accordance with a movement amount set corresponding to the elevation angle of the directional beam with the push reference position as a reference, and after adjusting the elevation angle of the directional beam The moving body satellite broadcast receiving apparatus according to claim 1 , wherein the pushing member is moved until a base end of the pushing member comes into contact with the wall member . The elevation angle adjusting mechanism, in the antenna element and the contact portion opposite the base end side of the pushing member includes a conductive member provided in the extrusion reference position of the pusher member,
The drive mechanism moves the push member in accordance with a movement amount set corresponding to the elevation angle of the directional beam with the push reference position as a reference, and after adjusting the elevation angle of the directional beam The mobile broadcast satellite receiver according to claim 1 , wherein the push member is moved until a base end of the push member contacts the conductive member . For the antenna element, an optical sensor is provided at a position on the rotating unit where a directional beam having a predetermined elevation angle is obtained,
The mobile satellite broadcast receiver according to any one of claims 1 to 6, wherein the elevation angle adjustment mechanism identifies a moving position of the antenna element based on an output of an optical sensor.   8. The mobile satellite broadcast receiving apparatus according to claim 7, wherein a mechanical switch is provided instead of the optical sensor. There are a plurality of positions at which the directional beam having the predetermined elevation angle is obtained, and an optical sensor is provided at each position.
8. The mobile satellite broadcast receiving apparatus according to claim 7, wherein the elevation angle adjusting mechanism operates only an optical sensor provided at a corresponding position in accordance with an elevation angle to be adjusted.   2. The elevation angle adjusting mechanism, when displacing the antenna element relative to the rotating portion, increases the driving force at the start of displacement and decreases the driving force before the end of displacement. The satellite broadcast receiver for mobile objects according to any one of? The mechanical switch is
The antenna element, wherein becomes the first state when the directional beam elevation predetermined is in position on the rotating part to be obtained, the first state and the second Naru different when in the other position Jo on purpose for Turkey and mobile object satellite broadcast receiver apparatus according to claim 8, wherein.   The design value and a value before and after the design value can be selected as the displacement amount of the antenna element corresponding to the elevation angle to be adjusted with respect to the rotating portion. The satellite broadcast receiver for mobile bodies in any one of 1-11.   The movement according to any one of claims 1 to 12, wherein the elevation angle adjusting mechanism can confirm whether or not the displacement of the antenna element is correctly performed by comparing before and after the displacement. Body satellite receiver.   The elevation angle adjustment mechanism can move the antenna element to a position corresponding to a plurality of elevation angles, and can move the antenna element from a position corresponding to one elevation angle directly to a position corresponding to another elevation angle. The satellite broadcast receiving apparatus for mobile bodies according to claim 1.   The elevation angle adjusting mechanism is capable of moving the antenna element to a position corresponding to a plurality of elevation angles, and when moving the antenna element from a position corresponding to one elevation angle to a position corresponding to another elevation angle. 14. The antenna element according to claim 1, wherein the antenna element is once moved to a position corresponding to an elevation angle closest to one side and then moved to a position corresponding to the other elevation angle. Satellite broadcasting receiver for mobiles.   16. The elevation angle adjusting mechanism moves the antenna element at a relatively low speed near a position corresponding to the elevation angle and at a relatively high speed in other portions. The satellite broadcast receiver for mobile units described in 1. The positioning mechanism is provided with reflective optical sensors at positions on both sides that are symmetric with respect to the axis, facing the periphery of the rotating portion.
The rotation unit is provided with a reflection adjusting unit at a position facing the reflection type optical sensor when positioned at the rotation reference position so that a reflection state is different from other positions. The satellite broadcast receiver for mobile bodies according to any one of claims 1 to 16. The positioning mechanism is provided with a reflective optical sensor in one place facing the periphery of the rotating part,
The rotation unit is provided with a reflection adjustment unit at a position facing the reflection type optical sensor when positioned at the rotation reference position so that a reflection state is different from other positions.
When the antenna element needs to be displaced in the opposite direction after the antenna element is pushed and displaced in one direction at the positioned position, the elevation angle adjusting mechanism displaces the rotating part by 180 °. 16. The mobile satellite broadcast receiving apparatus according to claim 1, wherein the antenna element is pushed and displaced in the one direction.   19. The mobile satellite broadcast receiving apparatus according to claim 17, wherein a mechanical switch is used in place of the combination of the reflective optical sensor and the reflection adjusting unit. Comprising a stop detection device for detecting whether or not the moving body is stopped;
20. The mobile satellite according to claim 1, wherein the elevation angle adjustment mechanism performs the elevation angle adjustment when it is detected by the stop detection device that the mobile body is stopped. Broadcast receiving device. A flatness detecting device for detecting whether or not a place where the moving body is present is flat;
The said elevation angle adjustment mechanism performs the said elevation angle adjustment, when it detects that the moving body exists in a flat place with a flat detection apparatus, The elevation angle adjustment mechanism according to any one of claims 1 to 19 Mobile satellite broadcasting receiver. A display unit for displaying which reception area corresponds to the elevation angle of the antenna element adjusted by the elevation angle adjustment mechanism;
It further includes an input unit that can specify a reception area by a user operation, and a control unit that controls the elevation angle adjustment mechanism so that the elevation angle of the antenna element is switched to an elevation angle corresponding to the reception area specified by the input unit. The mobile satellite broadcast receiver according to any one of claims 1 to 21.   23. The movement according to claim 22, wherein the control unit detects the reception level of the satellite broadcast before and after switching of the reception area, and notifies the user on the display unit when the reception level is lowered due to the switching. Body satellite receiver.   24. The control unit can switch to elevation angles corresponding to a plurality of reception areas, calculate a satellite broadcast reception level, and select an elevation angle at which the reception level is maximum. The satellite broadcast receiver for mobile units described. A navigation device that detects a current position of the mobile body based on prestored map information;
25. The mobile satellite broadcast receiving apparatus according to claim 24, wherein the control unit detects the elevation angle switching timing based on a current position detected by the navigation apparatus and map information. A terrestrial receiver for receiving terrestrial broadcast radio waves at the current position of the mobile body;
25. The satellite broadcast receiving device for mobile units according to claim 24, wherein the control unit detects timing for switching an elevation angle based on a terrestrial broadcast station received by the terrestrial wave receiving device.

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