JP2012010409A - Antenna device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an antenna device capable of suppressing sensitivity degradation as much as possible even with a low posture not more than 70 mm, and capable of receiving AM broadcast and FM broadcast.SOLUTION: An antenna board 30 is mounted with being erected on a plate-like antenna base 20, and a top part 31 is arranged so that the antenna board 30 is straddled. An antenna element is constituted by the top part 31 and an antenna pattern formed on the antenna board 30, and while a gap between a lower edge bent in a downward direction of the top part 31 and the antenna base 20 is made more than about 10 mm, a magnitude of the top part 31 is made to be the magnitude by which an antenna capacity of the antenna element becomes not less than about 3 pF. A reception signal from the antenna element is guided to an amplifier substrate 34 via a connection line 33 and is amplified. An antenna device 1 is constituted with an antenna case 10 fitted to the antenna base 20.

Description

  The present invention relates to a low-profile antenna device attached to a vehicle capable of receiving AM broadcast and FM broadcast.

  A conventional antenna device attached to a vehicle is generally an antenna device capable of receiving AM broadcast and FM broadcast. In this antenna apparatus, a rod antenna having a length of about 1 m has been conventionally used to receive AM broadcast and FM broadcast. The length of this rod antenna is about ¼ wavelength in the FM wave band, but in the AM wave band, the length is much shorter than the wavelength, so the sensitivity is significantly reduced. For this reason, conventionally, a high impedance cable is used to increase the impedance of the rod antenna with respect to the AM wave band, or amplification is performed using an AM wave band amplifier to ensure sensitivity. In addition, a vehicle-mounted antenna device is used in which the length of the antenna is shortened to about 180 mm to 400 mm by using a helical antenna wound around the rod portion of the antenna. However, an amplifier is inserted directly under the antenna in order to compensate for the performance deterioration due to the reduction of the rod portion.

FIG. 70 is a side view showing the configuration of a conventional antenna device 100 in which the rod portion is shortened. A conventional antenna device 100 shown in FIG. 70 includes an element 110 and an antenna base 111 to which a lower end of the element 110 is rotatably attached within a predetermined angle range. The antenna base 111 includes an antenna cover and an antenna base. An amplifier and a matching circuit are built in the antenna cover, and the antenna base is fitted on the lower surface of the antenna cover. A bolt portion for attaching the antenna device 100 to the vehicle body protrudes from the lower surface of the antenna base. The antenna device 1 is an antenna that receives AM broadcast and FM broadcast. The length of the element 110 is about 180 mm, and the total height h100 from the lower surface of the antenna base 111 to the tip of the element 110 is about 195 mm. The element 110 includes a helical element and an element cover that covers the helical element.
Further, in the antenna device 100, a side view showing a state in which the height 110 from the lower surface of the antenna base 111 to the tip of the element 110 is about 70 mm by rotating the element 110 in a direction perpendicular to the antenna base 111. 71.

JP-A-2005-223957 JP2003-188619

In such a conventional antenna device 100, when the antenna device 100 is attached to the vehicle body, the element 110 protrudes greatly from the vehicle body, so that the aesthetics / design of the vehicle is impaired, and the rod that is tilted down during garage entry or car washing, etc. If the user forgets to wake up the antenna, the antenna performance remains lost. Further, since the antenna device 100 is exposed outside the vehicle, the element 110 may be stolen. Therefore, an in-vehicle antenna device in which an antenna is housed in an antenna case can be considered. In this case, the height of the antenna device protruding from the vehicle is limited to a height of 70 mm or less by the vehicle external protrusion regulation, and the length in the longitudinal direction is preferably about 160 to 220 mm so as not to impair the appearance of the vehicle. . The radiation resistance Rrad of such an antenna is substantially determined in proportion to the square of the height of the antenna as expressed as 600 to 800 × (height / wavelength) ² . For example, when the element 110 is rotated in the antenna device 100 and the antenna height is lowered from about 195 mm shown in FIG. 70 to about 70 mm shown in FIG. 71, the sensitivity deteriorates by about 7 dB. As described above, there is a problem that if the height of the element 110 is simply lowered, the performance is greatly deteriorated and it is difficult to put it to practical use. Furthermore, since the radiation resistance Rrad is reduced when the antenna is placed in a low posture of 70 mm or less, the radiation efficiency is liable to decrease due to the influence of the conductor loss of the antenna itself, which causes further sensitivity deterioration. there were.

  Accordingly, an object of the present invention is to provide an antenna device capable of receiving AM broadcasting and FM broadcasting that can suppress sensitivity degradation as much as possible even when the posture is low at 70 mm or less.

  In order to achieve the above object, the present invention is an antenna device that includes an antenna case and an antenna portion that is housed in the antenna case, and projects at a height of about 70 mm or less when attached. On the antenna base that is fitted to the lower end of the antenna case, an antenna substrate having an antenna pattern formed thereon is erected, the cross-sectional shape is formed in a mountain shape so as to straddle the antenna substrate, and the rear portion is the antenna. The top part constituting the antenna element is arranged together with the antenna pattern protruding rearward from the rear end of the base, and the distance between the lower edge of the side part which is the slope of the top part and the antenna base is about 10 mm or more It is the main feature that it is said.

  According to the present invention, the cross-sectional shape of the top portion is formed in a mountain shape, and the rear portion protrudes rearward from the rear end of the antenna base. Can be made as small as possible, and the reactive capacity of the antenna capacity can be minimized. In addition, the distance between the lower edge of the side portion, which is the slope of the top portion, and the antenna base is about 10 mm or more, and the antenna capacity of the antenna element including the top portion and the antenna pattern is about 3 pF or more. As a result, even when the antenna device protrudes at a height of 70 mm or less when attached, the antenna performance almost equivalent to that of the conventional antenna device having a height of about 195 mm can be obtained.

It is a top view which shows the structure of the antenna apparatus concerning the Example of this invention. It is a front view which shows the structure of the antenna apparatus concerning the Example of this invention. It is a side view which shows the structure of the antenna apparatus concerning the Example of this invention. It is a top view which shows the internal structure of the antenna apparatus concerning the Example of this invention. It is a front view which shows the internal structure of the antenna apparatus concerning the Example of this invention. It is a right view which shows the internal structure of the antenna apparatus concerning the Example of this invention. 1 is an exploded view of an antenna device according to an embodiment of the present invention. It is a top view which shows the structure which abbreviate | omitted the antenna case and base pad of the antenna apparatus concerning this invention. It is a front view which shows the structure which abbreviate | omitted the antenna case and base pad of the antenna apparatus concerning this invention. It is a right view which shows the structure which abbreviate | omitted the antenna case and base pad of the antenna apparatus concerning this invention. It is a bottom view which shows the structure which abbreviate | omitted the antenna case and base pad of the antenna apparatus concerning this invention. It is a top view which shows the structure of the antenna case concerning the antenna apparatus of this invention. It is a front view which shows the structure of the antenna case concerning the antenna apparatus of this invention. It is a left view which shows the structure of the antenna case concerning the antenna apparatus of this invention. It is a top view which shows the structure of the top part concerning the antenna apparatus of this invention. It is a front view which shows the structure of the top part concerning the antenna apparatus of this invention. It is a bottom view which shows the structure of the top part concerning the antenna apparatus of this invention. It is a right view which shows the structure of the top part concerning the antenna apparatus of this invention. It is the front view and side view which show the structure of the coil concerning the antenna apparatus of this invention. It is the top view which shows the structure of the connecting wire concerning the antenna apparatus of this invention, a front view, and a right view. It is a top view which shows the structure of the amplifier board | substrate concerning the antenna apparatus of this invention. It is a front view which shows the structure of the amplifier board | substrate concerning the antenna apparatus of this invention. It is the top view which shows the structure of the hook concerning the antenna apparatus of this invention, a bottom view, a side view, and a front view. It is a top view which shows the structure of the antenna base concerning the antenna apparatus of this invention. It is a front view which shows the structure of the antenna base concerning the antenna apparatus of this invention. It is a right view which shows the structure of the antenna base concerning the antenna apparatus of this invention. It is a top view which shows the structure of the base pad concerning the antenna apparatus of this invention. It is a front view which shows the structure of the base pad concerning the antenna apparatus of this invention. It is a right view which shows the structure of the base pad concerning the antenna apparatus of this invention. It is a top view which shows the structure of the connection metal fitting concerning the antenna apparatus of this invention. It is a bottom view which shows the structure of the connection metal fitting concerning the antenna apparatus of this invention. It is a front view which shows the structure of the connection metal fitting concerning the antenna apparatus of this invention. It is a side view which shows the structure of the connection metal fitting concerning the antenna apparatus of this invention. It is a front view which shows the structure of the antenna board | substrate concerning the antenna apparatus of this invention. It is a side view which shows the structure of the antenna board | substrate concerning the antenna apparatus of this invention. It is a figure which shows the state which attached the connection metal fitting, the coil, and the connection line to the antenna board | substrate concerning the antenna apparatus of this invention. It is a figure which shows the frequency characteristic in the FM wave band of the average gain in the antenna apparatus of this invention in contrast with the antenna apparatus of a prior art example. It is a figure which shows the frequency characteristic of the AM wave band of S / N ratio in the antenna apparatus of this invention in contrast with the antenna apparatus of a prior art example. It is a figure which shows the frequency characteristic of the FM wave band of S / N ratio in the antenna apparatus of this invention in contrast with the antenna apparatus of a prior art example. It is a top view which shows the structure of the antenna apparatus used for the basic experiment of top part back protrusion length. It is a front view which shows the structure of the antenna apparatus used for the basic experiment of top part back protrusion length. It is a right view which shows the structure of the antenna apparatus used for the basic experiment of top part back protrusion length. It is a top view which shows the one aspect | mode of the antenna apparatus used for the basic experiment of top part back protrusion length. It is a figure which shows the frequency characteristic of the average gain in the FM wave band at the time of changing the moving amount L to the back of the top part from a standard position, and moving back. It is a figure which shows the change characteristic of the S / N ratio in the AM wave band at the time of changing back movement amount L of the top part from a standard position, and moving back. It is another figure which shows the change characteristic of the S / N ratio in the AM wave band at the time of changing back movement amount L of the top part from a standard position, and moving back. FIG. 10 is still another diagram showing a change characteristic of the S / N ratio in the AM wave band when the rearward movement amount L of the top portion from the standard position is changed and moved backward. It is a figure which shows the change characteristic of the S / N ratio in the FM wave band at the time of changing back movement amount L of the top part from a standard position, and moving back. It is another figure which shows the change characteristic of S / N ratio in the FM wave band at the time of changing back movement amount L of the top part from a standard position, and moving back. FIG. 11 is still another diagram showing the change characteristic of the S / N ratio in the FM wave band when the rearward movement amount L of the top portion from the standard position is changed and moved backward. It is a right view which shows the structure of the antenna apparatus used for the basic experiment which changes the height from the antenna base of a top part. It is a front view which shows the structure of the antenna apparatus used for the basic experiment which changes the height from the antenna base of a top part. It is a top view which shows the structure of the antenna apparatus used for the basic experiment which changes the height from the antenna base of a top part. It is a top view which shows the one aspect | mode of the antenna apparatus used for the basic experiment which changes the height from the antenna base of a top part. It is a right view which shows the one aspect | mode of the antenna apparatus used for the basic experiment which changes the height from the antenna base of a top part. It is a figure which shows the frequency characteristic of the average gain in the FM wave band when the height of a top part is made high gradually. It is a figure which shows the change characteristic of S / N ratio in the AM wave band when the height of a top part is made high gradually. It is another figure which shows the change characteristic of S / N ratio in the AM wave band when the height of a top part is made high gradually. FIG. 12 is still another diagram showing the change characteristic of the S / N ratio in the AM wave band when the height of the top portion is gradually increased. It is a figure which shows the change characteristic of S / N ratio in the FM wave band when the height of a top part is made high gradually. It is another figure which shows the change characteristic of S / N ratio in the FM wave band at the time of making height of a top part gradually high. FIG. 10 is still another diagram showing the change characteristic of the S / N ratio in the FM wave band when the height of the top portion is gradually increased. It is the front view and side view which show the 1st structure used for the basic experiment of the antenna capacity | capacitance at the time of changing the area which faces the antenna base of a top part. It is the front view and side view which show the 2nd structure used for the basic experiment of the antenna capacity | capacitance at the time of changing the area which faces the antenna base of a top part. It is the front view and side view which show the 3rd structure used for the basic experiment of the antenna capacity | capacitance at the time of changing the area which faces the antenna base of a top part. It is a figure which shows the change characteristic of the antenna capacity | capacitance at the time of changing a clearance in a 1st structure. It is a figure which shows the change characteristic of the antenna capacity | capacitance at the time of changing a clearance in a 2nd structure. It is a figure which shows the change characteristic of the antenna capacity | capacitance at the time of changing a clearance in a 3rd structure. It is a figure which shows the equivalent circuit of the antenna apparatus of this invention. It is a side view which shows the structure of the conventional antenna device. It is a side view which shows the structure at the time of making the height of the conventional antenna device low.

The configuration of an antenna device according to an embodiment of the present invention is shown in FIGS. 1 is a plan view showing the configuration of the antenna device 1 according to the present invention, FIG. 2 is a front view showing the configuration of the antenna device 1 according to the present invention, and FIG. 3 is the antenna device 1 according to the present invention. 4 is a plan view showing the internal configuration of the antenna device 1 according to the present invention. FIG. 5 is a front view showing the internal configuration of the antenna device 1 according to the present invention. 6 is a right side view showing the internal configuration of the antenna device 1 according to the present invention.
The antenna device 1 according to the embodiments of the present invention shown in these drawings is an antenna device attached to the roof of a vehicle, and the height h protruding from the vehicle when attached to the vehicle is about 70 mm. Yes. The antenna device 1 has an extremely low attitude (the height h is about 0.0023λ or less when the wavelength of the frequency of 100 MHz is λ), but can receive AM broadcast and FM broadcast. The antenna device 1 has a streamlined shape that becomes thinner toward the tip, and can be freely determined within a certain range so as not to impair the aesthetics and design of the vehicle. A flexible base pad made of rubber or elastomer is fitted on the lower surface of the antenna device 1 so that it can be attached to the vehicle in a watertight manner.

  An antenna device 1 according to an embodiment of the present invention is attached to a resin antenna case 10, a metal antenna base 20 to which a lower portion of the antenna case 10 is fitted, and the antenna base 20 vertically. The antenna board 30 and the amplifier board 34 attached in parallel, the top part, and the side part formed into a slope from both sides of the top part are formed in a cross-sectional shape, and are arranged on top so as to straddle the antenna board 30 And a GPS antenna 32 mounted on the antenna base 20. The antenna case 10 is made of a radio wave transmitting synthetic resin, and has a streamlined outer shape that becomes thinner toward the tip. In the antenna case 10, there are formed a space in which the upright antenna substrate 30 and the top portion 31 disposed on the antenna substrate 30 can be stored, and a space in which the amplifier substrate 34 is stored in the horizontal direction. A metal antenna base 20 is fitted on the lower surface of the antenna case 10. An antenna substrate 30 is erected and fixed to the antenna base 20, and an amplifier substrate 34 is fixed substantially parallel to the antenna base 20 in front of the antenna substrate 30. As will be described later, an antenna pattern is formed on the upper portion of the antenna substrate 30. A top portion 31 is built in the upper portion of the antenna case 10. Then, by fitting the antenna case 10 to the antenna base 20, the top portion 31 built in the antenna case 10 is disposed so as to straddle the upper portion of the antenna substrate 30, and the connection fitting attached to the upper portion of the antenna substrate 30. 36 comes into electrical contact with the inner surface of the top portion 31. Since the connection fitting 36 is electrically connected to the antenna pattern formed on the antenna substrate 30, the top portion 31 and the antenna pattern are connected via the connection fitting 36. As a result, an antenna element is constituted by the antenna pattern and the top portion 31, and the antenna substrate 30, the top portion 31, and the amplifier substrate 34 are accommodated in the space inside the antenna case 10.

  A coil 35 is provided on the antenna substrate 30 to resonate an antenna element constituted by the antenna pattern and the top portion 31 in the vicinity of the FM waveband. One end of the coil 35 is connected to the antenna pattern, the other end of the coil 35 is connected to one end of the pattern formed on the antenna substrate 30, and one end of the connection line 33 is connected to the other end of the pattern. The other end of the connection line 33 is connected to an input portion of an AM / FM amplifier provided on the amplifier board 34, and an AM / FM reception signal received by an antenna element constituted by the antenna pattern and the top portion 31 is AM. The signal is input to the / FM amplifier and amplified. Further, a bolt portion 21 for attaching the antenna device 1 to the vehicle is formed so as to protrude from the lower surface of the antenna base 20. A cable 22 for guiding a received signal from the antenna device 1 into the vehicle is led out from the lower surface of the antenna base 20. The cable 22 is led out from the amplifier board 34 and includes a cable for guiding the AM reception signal and the FM reception signal amplified by the AM / FM amplifier provided on the amplifier board 34, and is bundled by a collar 45. ing. In this case, holes through which the bolt part 21 and the cable 22 are inserted are formed in the roof of the vehicle, and the antenna device 1 is placed on the roof so that the bolt part 21 and the cable 22 are inserted into these holes. The antenna device 1 can be fixed to the roof of the vehicle by fastening a nut to the bolt portion 21 protruding into the vehicle. Further, power to the amplifier board 34 accommodated in the antenna case 10 is supplied to the amplifier board 34 from the inside of the vehicle via the cable 22.

An exploded view of the antenna device 1 according to the present invention is shown in FIG.
The assembly of the antenna device 1 according to the present invention will be described with reference to FIG. 7. The top portion 31 is fixed to the upper part of the antenna case 10 with two screws 40. A connection fitting 36 is fitted to the upper end of the antenna substrate 30. The connection fitting 36 is attached to the upper portion of the antenna substrate 30 by sandwiching the antenna substrate 30. A coil 35 is soldered on the antenna substrate 30 and attached. The antenna substrate 30 is erected and fixed to the antenna base 20 with two screws 41. The amplifier board 34 is disposed in front of the antenna board 30 and is fixed to the antenna base 20 substantially in parallel by three screws 42. A cable 22 for outputting amplified AM reception signals and FM reception signals is led out from the amplifier board 34, and a terminal 43 is attached to the tip of the cable 22, and the terminal 43 is fixed to the back surface of the amplifier board 34. Further, one end of a wire-like connection line 33 is connected to the antenna substrate 30, and the other end of the connection line 33 is connected to the amplifier substrate 34, whereby the output end of the coil 35 provided on the antenna substrate 30 and the amplifier substrate are connected. The AM / FM reception signal received by the antenna element constituted by the antenna pattern and the top portion 31 is connected to the input end of the AM / FM amplifier provided in 34, and the AM / FM amplifier in the amplifier board 34 is connected to the AM / FM amplifier. It will be entered. A collar 45 is fitted to the root of the cable 22 so as to bundle the cables 22 drawn from the drawing holes of the antenna base 20.

A hook 44 is disposed under the amplifier board 34 and is fitted to the antenna base 20. A pair of elongated engaging legs are extended from both side surfaces of the hook 44. When the antenna device 1 is attached to the vehicle, the engagement leg portion is engaged with an edge of an attachment hole formed in the vehicle, and serves to temporarily fix the antenna device 1 to the vehicle body. As a result, when the nut 47 is screwed into the bolt portion 21 from the inside of the vehicle without holding the antenna device 1 from the outside of the vehicle body, the antenna device 1 can be screwed without coming out of the mounting hole.
A base pad 24 is fitted on the lower surface of the antenna base 20. A hole portion through which a total of five screw heads can be inserted is formed in the peripheral portion of the base pad 24, and five screws 46 are inserted into the hole portion from below, and the screws 46 are attached to the antenna base 20. It is inserted into a fitting hole formed in the peripheral edge and screwed to the peripheral edge of the lower surface of the antenna case 10. Thereby, the antenna apparatus 1 can be assembled. When the assembled antenna device 1 is mounted by aligning the bolt part 21 in a mounting hole formed in the vehicle, the antenna device 1 is temporarily fixed to the mounting hole by the hook 44 as described above. In this state, the antenna device 1 can be attached to the vehicle body by screwing the nut 47 into the bolt portion 21 from the inside of the vehicle.

The structure of the antenna device 1 assembled as shown in FIG. 7 is shown in FIGS. 8 is a plan view showing the configuration of the antenna device 1 according to the present invention, FIG. 9 is a front view showing the configuration of the antenna device 1 according to the present invention, and FIG. 10 is the antenna device 1 according to the present invention. FIG. 11 is a bottom view showing the configuration of the antenna device 1 according to the present invention. However, in FIGS. 8 to 11, the antenna case 10 and the base pad 24 are omitted.
Although the description of these drawings is as described above, the description is omitted. However, the antenna substrate 30 is installed upright on the antenna base 20 with two screws 41, and a notch 30i is provided at the lower end of the antenna substrate 30. The GPS antenna 32 can be attached to the antenna base 20 so as to be partially accommodated in the notch 30i. When the GPS antenna 32 is attached, the cable is led out along the cable 22 from the GPS antenna 32 as well. Further, the distance between the lower edge of the side portion that is the slope of the top portion 31 disposed so as to straddle the upper portion of the antenna substrate 30 and the upper surface of the antenna base 20 is h10, and the interval h10 is about 34.4 mm, for example. Has been. The GPS antenna 32 is attached only when necessary. In addition, the rear portion of the top portion 31 is cut obliquely and protrudes rearward from the rear end of the antenna base 20, so that the area facing the antenna base 20 is reduced as much as possible.

Next, the structure of each part which comprises the antenna apparatus 1 is shown. The structure of the antenna case 10 is shown in FIGS. However, FIG. 12 is a plan view showing the configuration of the antenna case 10, FIG. 13 is a front view showing the configuration of the antenna case 10, and FIG. 14 is a left side view showing the configuration of the antenna case 10.
As shown in these drawings, the antenna case 10 is made of a radio wave-transmitting synthetic resin and has a streamlined outer shape that becomes thinner toward the tip. In the antenna case 10, there are formed a space in which the antenna substrate 30 erected and the top portion 31 disposed on the antenna substrate 30 can be accommodated, and a space in which the amplifier substrate 34 can be accommodated in the lateral direction.

The structure of the top part 31 is shown in FIGS. 15 is a plan view showing the configuration of the top portion 31, FIG. 16 is a front view showing the configuration of the top portion 31, FIG. 17 is a bottom view showing the configuration of the top portion 31, and FIG. 4 is a right side view showing a configuration of a top portion 31. FIG.
The top portion 31 shown in these drawings is formed by processing a metal plate, has a top portion that is a curved surface that gently falls toward the front, and a first side portion 31a that is inclined from the top portion to both sides; A second side portion 31b is formed. The slopes of the first side part 31a and the second side part 31b are steep slopes. Three slits 31f are formed in the first side portion 31a and the second side portion 31b, and each of the side portions 31a and 31b is composed of four pieces. A pair of pieces from almost the center of these pieces is a contact piece 31c. The contact piece 31c is bent and formed so as to be substantially vertical from the middle. Further, two flat portions 31e are formed at the top of the top portion 31, and screw holes 31d are formed in the flat portion 31e. The screws 40 are respectively inserted into the screw holes 31 d and screwed into the inside of the top of the antenna case 10, whereby the top portion 31 is built in the antenna case 10.

  When the length of the top portion 31 is L20, the width of the rear end is w20, the width of the front end is w21, and the height is h20, for example, the length L20 is about 106 mm, the rear end width w20 is about 28 mm, The width w21 is about 19 mm, and the height h20 is about 28 mm. The narrow width w22 of the top portion of the top portion 31 is about 4 mm. The reason why the slopes of the first side part 31a and the second side part 31b of the top part 31 are steep slopes is to match the sectional shape inside the antenna case 10, but mainly the top part 31 and the antenna. This is for reducing the stray capacitance between the top portion 31 and the antenna base 20 by reducing the area facing the base 20. This stray capacitance becomes an ineffective capacitance of the antenna capacitance and causes a reduction in antenna gain. Further, the rear portion of the top portion 31 is cut obliquely to reduce the area facing the antenna base 20 as much as possible.

  FIGS. 19A and 19B show the configuration of the coil 35. The coil 35 is for resonating an antenna element having a small antenna capacity formed of an antenna pattern formed on the top portion 31 and the antenna substrate 30 in the vicinity of the FM wave band. FIG. 19A is a front view showing the configuration of the coil 35, and FIG. 19B is a side view showing the configuration of the coil 35. The coil 35 shown in these drawings has a cylindrical coil body 35a around which the coil is wound, and two lead wires 35b drawn from the coil body 35a. The coil 35 is connected in series with the antenna element to resonate near the FM waveband. As described above, the antenna element of the antenna device 1 is constituted by the top portion 31 and the antenna pattern formed on the antenna substrate 30. The antenna capacity of this antenna element is about 4.7 pF. The antenna element can resonate in the vicinity of the FM wave band by inserting a coil 35 of about 0.5 μH to 3 μH in series. As a result, the antenna element including the top portion 31 and the antenna pattern operates favorably in the FM wave band due to the action of the coil 35. The antenna element that resonates in the FM wave band is used as a voltage receiving element in the AM wave band so as to receive the AM wave band.

  20A, 20B, and 20C show the configuration of the connection line 33. FIG. 20A is a plan view showing the configuration of the connection line 33, FIG. 20B is a front view showing the configuration of the connection line 33, and FIG. 20C is a right side view showing the configuration of the connection line 33. It is. A connection line 33 shown in these drawings is a connection line for guiding a reception signal output from the antenna substrate 30 to the amplifier substrate 34, and is formed by bending a wire-like conductor. The connection line 33 has a main body 33a that is bent in an L shape when viewed from the front. The upper end portion of the connection line 33 is formed into a U-shaped portion 33b bent in a U-shape, and is inserted into a long hole formed in the antenna substrate 30 and soldered. The lower end portion of the connection line 33 is a U-shaped portion 33c bent in a U-shape, and further has a bent portion 33d bent substantially parallel to the main body portion 33a at the tip. The bent portion 33d and the U-shaped portion 33c are inserted into the insertion holes formed in the amplifier substrate 34 and soldered.

  21 and 22 show the configuration of the amplifier substrate 34. FIG. 21 is a plan view showing the configuration of the amplifier board 34, and FIG. 22 is a front view showing the configuration of the amplifier board 34. As shown in FIG. As shown in these drawings, the amplifier board 34 is composed of a substantially rectangular board body 34a having a tapered front part. Three screw holes 34b are formed in the peripheral portion of the substrate body 34a, and an insertion hole 34b having a long hole is formed in the rear portion. The bent portion 33d and the U-shaped portion 33c formed in the lower portion of the connection line 33 are inserted into the insertion hole 34b and soldered. Screws 42 are respectively inserted into the three screw holes 34 b and screwed into the bosses 20 e of the antenna base 20, whereby the amplifier board 34 is fixed to the antenna base 20.

23A to 23D show the configuration of the hook 44. FIG. 23 (a) is a plan view showing the configuration of the hook 44, FIG. 23 (b) is a bottom view showing the configuration of the hook 44, FIG. 23 (c) is a side view showing the configuration of the hook 44, and FIG. d) is a front view showing the configuration of the hook 44.
The hook 44 shown in these drawings has a rectangular main body 44a, and a fitting leg 44b having a hook-like engagement piece formed at the tip is provided on one side from the four corners of the main body 44a downward. It is formed so as to oppose both side portions. Moreover, the long engaging leg part 44c is formed so that it may oppose below from the approximate center of the both sides of the other side. When attaching the hook 44 to the antenna base 20, the fitting leg portion 44 b engages with the edge of the rectangular hole formed in the antenna base 20, and the long engagement leg portion 44 c extends from the rectangular hole formed in the antenna base 20. It comes out and protrudes along the side surface of the bolt part 21. When the antenna device 1 is attached to the vehicle body, the engagement leg portion 44c engages with an edge portion of an attachment hole provided in the vehicle body, so that the antenna device 1 can be temporarily fixed so as not to come out.

The structure of the antenna base 20 is shown in FIGS. 24 is a plan view showing the configuration of the antenna base 20, FIG. 25 is a front view showing the configuration of the antenna base 20, and FIG. 26 is a right side view showing the configuration of the antenna base 20.
The antenna base 20 shown in these drawings has a main body portion 20a made of a substantially rectangular flat plate whose front portion is tapered, and a total of five insertion holes 20f are formed in the peripheral portion of the main body portion 20a. ing. The antenna case 10 is fitted to the antenna base 20 by screwing screws 46 respectively inserted into the fitting holes 20f from below into the periphery of the lower surface of the antenna case 10. Three bosses 20e are formed on the tapered front portion of the main body 20a. An amplifier board 34 is placed on the boss 20e and screws 42 inserted through the amplifier board 34 are respectively connected to the bosses 20e. The amplifier board 34 can be fixed to the antenna base 20 by being screwed to the antenna base 20.

  Further, two screw portions 20d are formed in the horizontal direction at substantially the center and the rear side of the main body portion 20a. The antenna board 30 can be erected and attached to the antenna base 20 by screwing screws 41 inserted into the mounting holes of the antenna board 30 into the screw portions 20d. A rectangular frame-shaped GPS antenna mounting portion 20b that forms a rectangular concave portion is formed slightly rearward from the center of the main body portion 20a, and screw holes 20c are formed at four corners of the GPS antenna mounting portion 20b. The GPS antenna 32 can be attached to the GPS antenna attachment portion 20b by screwing the four screws inserted through the attachment holes of the GPS antenna 32 into the screw holes 20c. A rectangular cable lead hole 20h is formed at the center of the main body 20a. From the cable drawing hole 20h, the cable 22 drawn from the amplifier board 34 and the cable drawn from the GPS antenna 32 can be drawn.

  Further, four first rectangular holes 20g and two second rectangular holes 20i are formed slightly on the front side from the center of the main body 20a. The four fitting legs 44b of the hook 44 are respectively inserted into the first rectangular holes 20g, and the hooks 44 are attached to the antenna base 20 by engaging the front ends thereof with the back surface of the antenna base 20. The two engagement legs 44c of the hook 44 are inserted into the second rectangular hole 20i and protrude along the bolt part 21 from the lower surface of the antenna base 20. A bolt portion 21 is formed so as to protrude from the back surface of the main body portion 20a, and a collar 45 is provided for bundling the cable 22 drawn out from the cable drawing hole 20h.

Next, the structure of the base pad 24 is shown in FIGS. 27 is a plan view showing the configuration of the base pad 24, FIG. 28 is a front view showing the configuration of the base pad 24, and FIG. 29 is a right side view showing the configuration of the base pad 24.
The base pad 24 shown in these drawings has a main body portion 24a made of a flat plate that has a shape that is a semicircular shape of an elongated oval shape that has a curved surface that gradually narrows toward the front portion and has a straight end. A peripheral wall portion 24b having a shape along the outer shape of the antenna base 20 is formed on the surface of 24a. The base pad 24 is fitted to the lower surface of the antenna base 20 by placing the antenna base 20 on the surface of the base pad 24 and fitting the peripheral edge of the antenna base 20 to the peripheral wall portion 24b. Further, a total of five holes 24d are formed along the peripheral wall 24b, and the heads of the screws 46 inserted from below into the insertion holes 20f of the antenna base 20 are inserted into the holes 24d. An elliptical cutout 24c is formed from the center to the front of the main body 24a, and the bolt 21, the cable 22 and the collar 45 provided on the lower surface of the antenna base 20 protrude from the cutout 24c. become.

Next, FIGS. 30 to 33 show the configuration of the connection fitting 36. 30 is a plan view showing the configuration of the connection fitting 36, FIG. 31 is a bottom view showing the configuration of the connection fitting 36, FIG. 32 is a front view showing the configuration of the connection fitting 36, and FIG. 4 is a side view showing a configuration of a connection fitting 36. FIG.
The connection fitting 36 shown in these drawings is formed by processing a metal plate having elasticity, and has a fitting main body 36a bent so that the central portion is folded. Clamping pieces 36c are formed on both sides of the front and rear parts of the metal fitting body 36a, and the two clamping pieces 36c are arranged to face each other so that the tips are in contact and the tips are opened. Has been. Further, a contact piece 36b formed longer than the holding piece 36c is formed between the two sets of holding pieces 36c so as to face each other. The contact piece 36b is expanded so as to expand downward, and the tip is curled in a semicircular shape outward. The connection fitting 36 is attached so as to sandwich the upper end of the antenna substrate 30. At this time, since the distal ends of the pair of sandwiching pieces 36c are open, it can be easily inserted between the sandwiching pieces 36c from the upper end of the antenna substrate 30. Further, when the connection fitting 36 is inserted into the upper portion of the antenna substrate 30, the connection fitting 36 is electrically connected to the antenna pattern formed on the upper portion of the antenna substrate 30. Further, when the antenna case 10 is fitted to the antenna base 20, the contact piece 36 b that is spread on the inner surface of the contact piece 31 c of the top portion 31 attached in the antenna case 10 comes into contact. As a result, the top portion 31 is electrically connected to the antenna pattern via the connection fitting 36.

Next, FIG. 34 and FIG. 35 show the configuration of the antenna substrate 30. However, FIG. 34 is a front view showing the configuration of the antenna substrate 30, and FIG. 35 is a side view showing the configuration of the antenna substrate 30.
The antenna substrate 30 shown in these drawings includes a substrate body 30a that is a printed circuit board such as a glass epoxy substrate having good high-frequency characteristics, and the substrate body 30a includes a protruding portion 30f that protrudes from an upper portion of a rectangular portion. A portion protruding from the lower left part to the left side is formed. An antenna pattern 30b is formed on both sides of the upper portion of the substrate body 30a and the protruding portion 30f, and an elongated pattern is formed on both sides of the left peripheral edge from the bottom of the antenna pattern 30b to a portion protruding from the lower left portion. The protrusion 30f is a part into which the connection fitting 36 is inserted, and projections 30h for positioning the connection fitting 36 are formed on both sides of the upper end of the protrusion 30f. Two attachment holes 30d are formed in the lower part of the substrate body 30a, and a notch 30i is formed between the attachment holes 30d. Ring-shaped patterns are formed on both sides around the mounting hole 30d, and the screws 41 are inserted into the mounting holes 30d and screwed into the screw portions 20d of the antenna base 20, whereby the antenna substrate 30 is formed. The antenna base 20 is installed upright. A GPS antenna 32 is attached to the antenna base 20 so as to be partially accommodated in the notch 30i.

  One of the lead wires 35b of the coil 35 is inserted into the hole 30g formed on the left side of the antenna pattern 30b and soldered to the antenna pattern 30b, and the other lead wire 35b is formed on the upper portion of the pattern 30c. It is inserted into the hole 30e and soldered to the pattern 30c. Further, the U-shaped portion 33b of the connecting line 33 is inserted into the long hole 30e formed in the lower portion of the pattern 30c and soldered to the pattern 30c. Thereby, the antenna pattern 30b is connected to the AM / FM amplifier provided on the amplifier substrate 34 to which the U-shaped portion 33c of the connection line 33 is connected via the coil 35, the pattern 30c, and the connection line 33.

  FIG. 36 shows a state where the connection fitting 36, the coil 35, and the connection line 33 are attached to the antenna substrate 30. As shown in this figure, a connection fitting 36 is sandwiched between projections 30h of the projecting portion 30f so as to sandwich the projecting portion 30f on the upper portion of the antenna substrate 30. The coil 35 is soldered between the hole 30g of the antenna pattern 30b and the long hole 30e of the pattern 30c. The U-shaped portion 33b of the connection line 33 is soldered to the long hole 30e of the pattern 30c.

In the antenna device 1 of the present invention, the distance h10 between the top portion 31 and the antenna base 20 is about 34.4 mm, the length L20 is about 106 mm in the dimensions of the top portion 31 shown in FIGS. FIG. 37 shows frequency characteristics of the average gain of the antenna device 1 when the width w20 is about 28 mm, the front end width w21 is about 19 mm, the height h20 is about 28 mm, and the width w22 is about 4 mm. A comparison with the conventional example is shown. However, the GPS antenna 32 is not attached to the antenna device 1.
The frequency band of the average gain in the antenna device 1 shown in FIG. 37 is the frequency band of the FM wave band of 76 MHz to 90 MHz. In the conventional antenna device 100, the total height h100 is about 195 mm (see FIG. 70). As Example 1, the case where the total height h100 is about 70 mm (see FIG. 71) is shown as Conventional Example 2. Referring to the frequency characteristics of the average gain of Conventional Example 1 and Conventional Example 2, it can be seen that when the total height h100 is lowered from about 195 mm to about 70 mm, the average gain is deteriorated by about 7 dB over the entire frequency band of the FM wave band. Referring to FIG. 37, the antenna device 1 of the present invention has an average gain equivalent to that of the conventional example 1 in which the total height h100 is about 195 mm even if the height h protruding when attached is about 70 mm. It can be seen that frequency characteristics are obtained, and that an improved average gain is obtained particularly in a high band of about 84 MHz or higher.

Next, in the antenna device 1 to which the GPS antenna 32 of the present invention is not attached, the frequency characteristics of the S / N ratio in the AM wave band when the dimensions are set as described above are shown in comparison with the conventional examples 1 and 2. 38.
The frequency band of the S / N ratio shown in FIG. 38 is the frequency band of the AM wave band of 531 kHz to 1602 kHz. FIG. 38 is based on the antenna device 100 of the conventional example 1, and the antenna input value that provides an S / N ratio of 20 dB in the antenna device 100 of the conventional example 1 is standardized to 0 dB. An antenna input value at which an S / N ratio of 20 dB is obtained in the antenna device 100 is shown as an input improvement value [dB] with respect to the normalized antenna input value. Referring to the frequency characteristics of the input improvement values of Conventional Example 1 and Conventional Example 2, when the total height h100 is lowered from about 195 mm to about 70 mm, the input improvement value is about 4.5 to about about the entire frequency band of the AM wave band. It can be seen that the degradation is 5 dB. That is, the S / N ratio deteriorates. Referring to FIG. 38, the antenna device 1 of the present invention can obtain a frequency characteristic of an input improvement value equal to or higher than that of the conventional example 1 in which the total height h100 is about 195 mm even if the height h is about 70 mm. It can be seen that an improved input improvement value is obtained as the frequency increases, and the S / N ratio is improved.

Next, in the antenna device 1 to which the GPS antenna 32 of the present invention is not attached, the frequency characteristic of the S / N ratio of the FM broadcast reception signal when the dimensions are set as described above is compared with the conventional example 1 and the conventional example 2. It shows in FIG.
The frequency band shown in FIG. 39 is an FM wave band of 76 MHz to 90 MHz. Also in FIG. 39, the antenna input value at which an S / N ratio of 30 dB is obtained in the antenna apparatus 100 of the conventional example 1 is standardized to 0 dB, and the S / N ratio of 30 dB in the antenna apparatus 1 of the present invention and the antenna apparatus 100 of the conventional example 2 Is shown as an input improvement value [dB] with respect to the normalized antenna input value. Referring to the frequency characteristics of the input improvement values of Conventional Example 1 and Conventional Example 2, when the total height h100 is lowered from about 195 mm to about 70 mm, the frequency band of the FM wave band is reduced by about 4 dB in the low band (76 MHz). It can be seen that the deterioration is only about 1 dB in the middle band (83 MHz), but it is degraded as it goes from the middle band to the high band, and 7 dB is degraded at 90 MHz. Referring to FIG. 39, the antenna device 1 of the present invention can obtain the frequency characteristics of the input improvement value equivalent to the conventional example 1 in which the total height h100 is about 195 mm even if the height h is about 70 mm. It can be seen that the S / N ratio is improved.

In the antenna device 1 of the present invention, when the top portion 31 protrudes rearward from the rear end of the antenna base 20, the average gain and the S / N ratio are improved. Thus, FIGS. 40 to 43 show aspects of the antenna device 1 in the basic experiment when the top portion 31 protrudes rearward from the rear end of the antenna base 20, and the basic experiment data obtained at that time are shown in FIGS. As shown in FIG. However, the GPS antenna 32 is not attached to the antenna device 1.
40 is a plan view showing the configuration of the antenna device 1 used in the basic experiment, FIG. 41 is a front view showing the configuration of the antenna device 1 used in the basic experiment, and FIG. 42 is the antenna device used in the basic experiment. 1 is a right side view showing a configuration of 1. FIG. As shown in these drawings, the shape of the top portion 31-1 in the antenna device 1 is slightly different from the top portion 31 of the embodiment, but the length and width are almost the same. It has the same electrical performance. The top part 31-1 is formed so that the top part is substantially flat, and both side parts are steeply inclined slopes downward. The rear part of the top part 31-1 is cut obliquely to reduce the area facing the antenna base 20 as much as possible. In the basic experiment of the top portion rearward protruding length, the movement amount L of the top portion 31-1 from the standard position is moved rearwardly to L1, L2, L3, and L4 as shown in FIGS. Here, the movement amounts L1, L2, L3, and L4 are about 10 mm, about 20 mm, about 30 mm, and about 40 mm, respectively. FIG. 43 is a front view showing the configuration when the amount of movement L of the top portion 31-1 is about 40 mm (L4).

  FIG. 44 shows frequency characteristics of the average gain in the FM wave band when the rearward movement amount L of the top portion 31-1 from the standard position is moved rearward to L1, L2, L3, and L4. The frequency band of the average gain shown in FIG. 44 is the frequency band of the FM wave band of 76 MHz to 90 MHz. Referring to FIG. 44, the frequency characteristic of the average gain is improved as the top portion 31-1 is moved backward from 0 mm to about 10 mm, about 20 mm, about 30 mm, and about 40 mm. Will come. When the amount of movement behind the top portion 31-1 is 0 mm and about 40 mm, when the amount of movement is about 40 mm, the frequency characteristic of the maximum gain is about 4 dB within the frequency band of the FM wave band. Will be improved.

  Next, the change characteristics of the S / N ratio in the AM wave band when the rearward movement amount L of the top portion 31-1 from the standard position is moved rearward to L1, L2, L3, and L4 are shown in FIG. It shows in FIG. 45 to 47 show the amount of movement by standardizing the antenna input value to 0 dB with an S / N ratio of 20 dB on the basis of the movement amount L to the rear of the top portion 31-1 being 0 mm at the frequency in the AM wave band. When L is moved from 0 mm to about 10 mm, about 20 mm, about 30 mm, and about 40 mm, an antenna input value that can obtain an S / N ratio of 20 dB is obtained as an input improvement value relative to the normalized antenna input value [dB ]. FIG. 45 shows the input improvement value for the protrusion length L, which is the movement amount L when the frequency is the lower limit value of 531 kHz, and FIG. 46 is the movement amount L when the frequency is approximately the center frequency of 999 kHz. 47 shows the input improvement value with respect to the protrusion length L, and FIG. 47 shows the input improvement value with respect to the protrusion length L, which is the movement amount L when the frequency is the upper limit value of 1602 kHz. Referring to these figures, at a frequency of 531 kHz, the input improvement value is improved as the protrusion length L is increased, and is improved by about 1.3 dB when the protrusion length L is 40 mm. . Further, even at a frequency of 999 kHz, the input improvement value is improved as the protrusion length L is increased, and is improved by about 0.8 dB when the protrusion length L is 40 mm. Further, even at a frequency of 1602 kHz, the input improvement value is improved as the protrusion length L is increased, and is improved by about 1.5 dB when the protrusion length L is 40 mm. Thus, in the AM wave band, the S / N ratio is improved as the protrusion length L is increased.

Next, the frequency characteristics of the S / N ratio in the FM wave band when the rearward movement amount L of the top portion 31-1 from the standard position is moved rearward to L1, L2, L3, and L4 are shown in FIG. As shown in FIG. 48 to 50 show the amount of movement by standardizing the antenna input value to 0 dB with an S / N ratio of 30 dB with respect to the amount of movement L to the rear of the top portion 31-1 as a reference at the frequency in the FM waveband. When L is moved from 0 mm to about 10 mm, about 20 mm, about 30 mm, and about 40 mm, an antenna input value that can obtain an S / N ratio of 30 dB is set as an input improvement value relative to the normalized antenna input value [dB ]. FIG. 48 shows an input improvement value with respect to the protrusion length L, which is the movement amount L when the frequency is the lower limit value of 76 MHz, and FIG. 49 shows the movement amount L when the frequency is substantially the center frequency of 83 MHz. The input improvement value with respect to the protrusion length L is shown, and FIG. 50 shows the input improvement value with respect to the protrusion length L, which is the movement amount L when the frequency is the upper limit value of 90 MHz. Referring to these figures, at a frequency of 76 MHz, the input improvement value is improved as the protrusion length L is increased, and is improved by about 1.2 dB when the protrusion length L is 40 mm. . Even at a frequency of 83 MHz, the input improvement value is improved as the protrusion length L is increased, and is improved by about 0.6 dB when the protrusion length L is 40 mm. Further, even at a frequency of 90 MHz, the input improvement value is improved as the protrusion length L is increased, and is improved by about 1.3 dB when the protrusion length L is 40 mm. Thus, the S / N ratio is improved as the protruding length L is increased in the FM wave band.
From the basic experiment described above, the distance from the ground increases as the top portion 31 is moved rearward, and the stray capacitance between the ground and the top portion 31 is reduced, so that gain and gain in both the AM wave band and the FM wave band are reduced. It can be seen that the S / N ratio is improved.

Next, a basic experiment for obtaining basic experimental data of average gain and S / N ratio when the height H of the top portion 31 and the antenna base 20 is changed in the antenna device 1 of the present invention will be described. A mode of the antenna device 1 in a basic experiment for changing the height H of the top portion 31 from the antenna base 20 is shown in FIGS. 51 to 55, and basic experiment data obtained at that time are shown in FIGS. However, the GPS antenna 32 is not attached to the antenna device 1.
51 is a right side view showing the configuration of the antenna device 1 used in the basic experiment, FIG. 52 is a front view showing the configuration of the antenna device 1 used in the basic experiment, and FIG. 53 is the antenna used in the basic experiment. 2 is a plan view showing a configuration of the device 1. FIG. As shown in these drawings, the shape of the top portion 31-2 in the antenna device 1 is slightly different from the top portion 31 of the embodiment, and the top portion 31- used in the basic experiment for moving the top portion backward as described above. It is set as the shape which enlarged the dimension of the both sides of 1. Both side portions of the top portion 31-2 that are inclined steeply downward are approximately 50 mm in the horizontal direction, and the downward dimension of the inclined surface is approximately 60 mm. In the basic experiment of the top portion height, as shown in FIGS. 51 to 53, the height H of the top portion 31-2 from the antenna base 20 is increased to H1, H2, H3, and H4. The heights H1, H2, H3, and H4 are about 5 mm, about 10 mm, about 20 mm, and about 30 mm, respectively. 54 is a front view showing a configuration when the height H of the top portion 31-2 is about 30 mm (H4), and FIG. 55 is a front view showing the height H of the top portion 31-2 is about 30 mm (H4). It is made into the right view which shows the structure at the time of doing.

  FIG. 56 shows frequency characteristics of the average gain in the FM wave band when the height H of the top portion 31-2 is gradually increased to H1, H2, H3, and H4. The frequency band of the average gain shown in FIG. 56 is the frequency band of the FM wave band of 76 MHz to 90 MHz. Referring to FIG. 56, the frequency characteristics of the average gain gradually improve as the height H of the top portion 31-2 from the antenna base 20 is increased from 5 mm to about 10 mm, about 20 mm, and about 30 mm. Comparing the case where the height of the top portion 31-2 is about 5 mm and the case where it is about 10 mm, when the height H is about 10 mm, the average gain is improved up to about 5 dB in the frequency band of the FM wave band. To come. When the height of the top portion 31-2 is about 5 mm and about 30 mm, when the height H is about 30 mm, the maximum gain is about 10 dB within the frequency band of the FM wave band. Will be improved.

  Next, FIGS. 57 to 59 show the change characteristics of the S / N ratio in the AM wave band when the height H of the top portion 31-2 is gradually increased to H1, H2, H3, and H4. 57 to 59, with respect to the frequency in the AM wave band, the antenna input value at which the S / N ratio is 20 dB is normalized to 0 dB with the height H from the antenna base 20 of the top portion 31-2 being 30 mm as a reference. When the height H is moved from 5 mm to about 10 mm, about 20 mm, and about 30 mm, an antenna input value that can obtain an S / N ratio of 20 dB is an input improvement value [dB] with respect to the normalized antenna input value. As shown. FIG. 57 shows the input improvement value with respect to the height H when the frequency is the lower limit value of 531 kHz, and FIG. 58 shows the input improvement value with respect to the height H when the frequency is substantially the center frequency of 999 kHz. FIG. 59 shows the input improvement value with respect to the height H when the frequency is set to the upper limit value of 1602 kHz. Referring to these figures, at a frequency of 531 kHz, when the height H is set to 5 mm, the input improvement value is improved as the height H is increased. When it is set to 30 mm, it is improved to 0 dB. Further, even at a frequency of 999 kHz, when the height H is set to 5 mm, the degradation is about 6 dB, but the input improvement value is improved as the height H is increased, and the height H is set to 30 mm. In this case, the noise is improved to 0 dB. Further, even at a frequency of 1602 kHz, when the height H is set to 5 mm, the degradation is about 6 dB, but the input improvement value is improved as the height H is increased, and the height H is set to 30 mm. In this case, the noise is improved to 0 dB. Thus, in the AM wave band, the S / N ratio is improved as the height H is increased.

Next, FIGS. 60 to 62 show frequency characteristics of the S / N ratio in the FM wave band when the height H of the top portion 31-2 is gradually increased to H1, H2, H3, and H4. 60 to 62, with respect to the frequency in the FM wave band, with reference to the height H from the antenna base 20 of the top portion 31-2 of 30 mm as a reference, the antenna input value for obtaining an S / N ratio of 30 dB is normalized to 0 dB. When the height H is moved from 5 mm to about 10 mm, about 20 mm, and about 30 mm, the antenna input value that can obtain the S / N ratio of 30 dB is shown as the input improvement value with respect to the standardized antenna input value. 60 shows the input improvement value with respect to the height H when the frequency is set to the lower limit of 76 MHz, and FIG. 61 shows the input improvement value with respect to the height H when the frequency is set to the center frequency of about 83 MHz. FIG. 62 shows the input improvement value with respect to the height H when the frequency is set to the upper limit value of 90 MHz. Referring to these figures, at a frequency of 76 MHz, when the height H is 5 mm, the degradation is about 6.4 dB. However, as the height H is increased, the input improvement value is improved and the height is increased. When H is set to 30 mm, it improves to 0 dB. Even at a frequency of 83 MHz, when the height H is set to 5 mm, the degradation is about 7.5 dB. However, as the height H is increased, the input improvement value is improved, and the height H is set to 30 mm. When it hits, it will improve to 0dB. Further, even at a frequency of 90 MHz, when the height H is set to 5 mm, the deterioration is about 4.5 dB. However, as the height H increases, the input improvement value is improved, and the height H is set to 30 mm. When it hits, it will improve to 0dB. Thus, the S / N ratio is improved as the height H is increased even in the FM waveband.
From the basic experiment described above, as the height H of the top portion 31 from the antenna base 20 is increased, the distance from the ground as the antenna base 20 is increased, and the stray capacitance between the ground and the top portion 31 is reduced. It becomes like this. Here, it can be seen that when the height H is about 10 mm or more, the gain and the S / N ratio are improved in both the AM wave band and the FM wave band.

Next, a basic experiment for obtaining basic experiment data of the antenna capacity when the area of the top portion 31 facing the antenna base 20 in the antenna device 1 of the present invention is changed will be described. An equivalent circuit of the antenna device 1 of the present invention is shown in FIG. The antenna element portion 50 in the equivalent circuit is composed of a top portion 31 and an antenna pattern 30b formed on the antenna substrate 30, and an antenna element induced voltage source V0 and an overall antenna capacitance Ca are connected in series. . A reception signal output from the antenna element unit 50 is input to an amplifier circuit unit 51 provided on the amplifier substrate 34. The amplifier circuit unit 51 is provided with an amplifier AMP, and the received reception signal is amplified and output from the output terminal OUT. In addition, an ineffective capacitor Ci serving as an amplifier input section capacitance is connected between the input side of the amplifier circuit section 51 and the ground. The reactive capacitance Ci is generated by stray capacitance with respect to the ground of the antenna element unit 50. The antenna input section voltage Vi of the received signal input to the amplifier AMP is obtained by the following equation (1).
Vi = V0 · Ca / (Ca + Ci) (1)
As shown in the equation (1), it can be seen that the smaller the reactive capacitance Ci is, the larger the antenna input section voltage Vi inputted to the amplifier AMP is, and the gain of the antenna device 1 is improved.

  Therefore, in a basic experiment for obtaining basic experiment data of the antenna capacity (Ca + Ci) when the area of the top portion 31 facing the antenna base 20 is changed, three types of top portions 31-3 having different areas are prepared. Then, the top portion 31-3 was arranged vertically and parallel to the antenna base 20, and the antenna capacity when the clearance S between them was changed was measured. The top portion 31-3 shown in FIGS. 63A and 63B has a horizontal length a1 of about 50 mm and a vertical length b1 of about 50 mm. FIG. 63A shows the top portion 31-3. FIG. 3 is a front view showing a configuration vertically arranged on an antenna substrate 30 standing on an antenna base 20, and the height of the antenna substrate 30 is a clearance S. FIG. 63B is a side view showing a configuration in which the top portion 31-3 is horizontally disposed on the antenna substrate 30 erected on the antenna base 20, and the height of the antenna substrate 30 is a clearance S. Yes. FIG. 66 shows a change characteristic of the antenna capacity when the clearance S is changed from about 10 mm to about 50 mm in the first configuration shown in FIGS. 63 (a) and 63 (b). Referring to FIG. 66, when the top portion 31-3 is arranged vertically as shown in FIG. 63 (a), the maximum antenna capacity is about 2.8 pF when the clearance S is 10 mm, and the clearance S is When the clearance S is 40 mm, the antenna capacity is about 1.9 pF. Further, as shown in FIG. 63 (b), when the top portion 31-3 is disposed horizontally, the area facing the antenna base 20 becomes large, and becomes maximum when the clearance S is 10 mm. When the clearance S is 40 mm, the antenna capacity is about 2 pF.

  Next, the top portion 31-3 shown in FIGS. 64 (a) and 64 (b) has a horizontal length a2 of about 50 mm and a vertical length b2 of about 25 mm. FIG. 64 (a) shows the top portion 31. -3 is a front view showing a configuration in which the antenna substrate 30 is vertically arranged on the antenna substrate 30 standing on the antenna base 20, and the height of the antenna substrate 30 is defined as a clearance S. FIG. 64B is a side view showing a configuration in which the top portion 31-3 is horizontally disposed on the antenna substrate 30 erected on the antenna base 20, and the height of the antenna substrate 30 is defined as a clearance S. Yes. FIG. 67 shows a change characteristic of the antenna capacity when the clearance S is changed from about 10 mm to about 50 mm in the second configuration shown in FIGS. 64 (a) and 64 (b). Referring to FIG. 67, when the top portion 31-3 is arranged vertically as shown in FIG. 64A, the maximum antenna capacity is about 2.1 pF when the clearance S is 10 mm, and the clearance S is When the clearance S is 40 mm, the antenna capacity is about 1.3 pF. Also, as shown in FIG. 64 (b), when the top portion 31-3 is disposed horizontally, the area facing the antenna base 20 becomes large, and when the clearance S is 10 mm, the maximum becomes about 3 pF. As the clearance S increases, the antenna capacity decreases to about 1.4 pF when the clearance S is 40 mm.

  Next, the top portion 31-3 shown in FIGS. 65 (a) and 65 (b) has a horizontal length a3 of about 50 mm and a vertical length b3 of about 3 mm. FIG. -3 is a front view showing a configuration in which the antenna substrate 30 is vertically arranged on the antenna substrate 30 standing on the antenna base 20, and the height of the antenna substrate 30 is defined as a clearance S. FIG. 65B is a side view showing a configuration in which the top portion 31-3 is horizontally disposed on the antenna substrate 30 erected on the antenna base 20, and the height of the antenna substrate 30 is a clearance S. Yes. FIG. 68 shows a change characteristic of the antenna capacity when the clearance S is changed from about 10 mm to about 50 mm in the third configuration shown in FIGS. 65 (a) and 65 (b). Referring to FIG. 68, when the top portion 31-3 is arranged vertically as shown in FIG. 65 (a), the maximum is obtained when the clearance S is 10 mm, and the antenna capacity is about 1 pF, and the clearance S is increased. When the clearance S is 40 mm, the antenna capacity becomes about 0.7 pF. Further, as shown in FIG. 65 (b), the same applies to the case where the top portion 31-3 is disposed horizontally. The maximum antenna capacity is about 1 pF when the clearance S is 10 mm, and the clearance S increases. When the clearance S is reduced to 40 mm, the antenna capacity becomes about 0.7 pF.

  The antenna capacity is the sum of the overall antenna capacity Ca and the reactive capacity Ci, and the reactive capacity Ci is a stray capacity generated by the facing area between the antenna element section 50 and the ground. In this case, the opposing area between the top portion 31-3 and the antenna base 20 is increased, and the reactive capacitance Ci is increased. Since the invalid capacity Ci decreases in inverse proportion to the clearance S, the antenna capacity decreases as the clearance S increases. In this case, the decreasing capacity is a capacity based on the reactive capacity Ci, and the overall antenna capacity Ca does not change even if the clearance S changes. Therefore, as shown in the change characteristics of the antenna capacity in FIGS. 66 to 68, it can be seen that the reactive capacity Ci is reduced by reducing the facing area between the top portion 31-3 and the antenna base 20. As described above, the reactive capacitance Ci decreases as the area of the top portion 31-3 is reduced. However, even if the area of the top portion 31-3 is increased, the reactive capacitance Ci can be reduced by arranging the top portion 31-3 vertically. . Then, in the top part 31 in the antenna apparatus 1 of the Example of this invention, it comprises the antenna base 20 by comprising by the 1st side part 31a and the 2nd side part 31b which were made into the slope which steeply inclined on the both sides from the top part. The reactive area is reduced by reducing the facing area.

The antenna device 1 according to the embodiment of the present invention described above has a low posture and a height of about 70 mm or less. In the antenna device 1, as described above, an antenna element is configured by the top portion 31 and the antenna pattern 30 b formed on the antenna substrate 30. The antenna capacity of the antenna element is about 4.7 pF. In this case, the height h10 from the lower edge of the top part 31 to the upper surface of the antenna base 20 is about 34.4 mm, and the dimension of the top part 31 is the above-described dimension. The antenna capacity in the antenna device 1 of the present invention is preferably about 3 pF or more so that the antenna element functions effectively as an antenna. In order to reduce the ineffective capacity, the height h10 from the lower edge of the top portion 31 indicated by the clearance S to the upper surface of the antenna base 20 is preferably about 10 mm or more. Further, by moving the rear portion of the top portion 31 so as to protrude rearward from the rear end of the antenna base 20, the electrical characteristics can be improved. Furthermore, the shape of the top portion 31 is not limited to the shape shown in FIGS. 15 to 18, and may be the shape of the top portion 31-1 shown in FIGS. 40 to 43.
In the above description, the top portion made of a metal plate is built in by attaching it to the antenna case. However, the top portion is deposited or adhered to the upper inner surface of the antenna case so that the top portion is placed in the antenna case. You may make it incorporate. Moreover, although the antenna device according to the present invention is mounted on a vehicle mounted on a roof or trunk of a vehicle, the present invention is not limited to this, and any antenna device that receives an AM wave band and an FM wave band can be applied.

DESCRIPTION OF SYMBOLS 1 Antenna apparatus, 10 Antenna case, 20 Antenna base, 20a Main body part, 20b Antenna mounting part, 20c Screw hole, 20d Screw part, 20e Boss, 20f Insertion hole, 20g Rectangular hole, 20h Cable extraction hole, 20i Rectangular hole, 21 Bolt part, 22 cable, 24 base pad, 24a body part, 24b peripheral wall part, 24c notch hole, 24d hole part, 30 antenna board, 30a board body, 30b antenna pattern, 30c pattern, 30d mounting hole, 30e long hole, 30f Projection part, 30g hole part, 30h protrusion, 30i notch, 31 top part, 31a first side part, 31b second side part, 31c contact piece, 31d screw hole, 31e flat part, 31f slit, 32 GPS antenna, 33 connection Line, 33a body, 33b U-shaped 33c U-shaped part, 33d bent part, 34 amplifier board, 34a board body, 34b screw hole, 34b insertion hole, 35 coil, 35a coil body, 35b lead wire, 36 connection fitting, 36a fitting body, 36b contact piece 36c Clamping piece, 40 screws, 41 screws, 42 screws, 43 terminals, 44 hooks, 44a main body, 44b fitting legs, 44c engaging legs, 45 collar, 46 screws, 47 nuts, 50 antenna element, 51 amplifier Circuit part, 100 antenna device, 110 element, 111 antenna base

Claims (3)

An antenna device comprising an antenna case and an antenna portion housed in the antenna case, and projecting at a height of about 70 mm or less when attached,
The antenna unit is
A conductive antenna base fitted to the lower end of the antenna case so as to close the lower surface of the antenna case;
An antenna substrate that is erected on the antenna base and on which an antenna pattern is formed;
A top part and side parts that are inclined from both sides of the top part are formed, and the cross-sectional shape is formed in a mountain shape, and is arranged so as to straddle the antenna substrate, and the vicinity of the top part is connected to the antenna pattern. An antenna element together with the antenna pattern, and a rear portion protruding backward from a rear end of the antenna base;
An amplifier for amplifying AM broadcast and FM broadcast signals received by the antenna element is provided, and an amplifier board disposed on the antenna base,
The distance between the lower edge of the side portion of the top portion and the antenna base is about 10 mm or more, and the antenna pattern on the antenna substrate is connected to the input of the amplifier on the amplifier substrate and the inductance of the antenna element. An antenna device, wherein the antenna device is connected through a coil for compensating for the minute.   The antenna device according to claim 1, wherein the top portion has a size such that an antenna capacity of the antenna element is about 3 pF or more. The antenna unit further includes a connection fitting having a contact piece that is attached so as to sandwich the upper part of the antenna substrate on which the antenna pattern is formed, and that is formed so as to spread on both sides,
When the antenna case is attached to the antenna base so as to cover the antenna part by the antenna case, the contact piece of the connection fitting is attached to the antenna case. The antenna device according to claim 1, wherein the top portion and the antenna pattern are electrically connected by contacting the inside of the side portion of the top portion.

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