The present application claims priority to Japanese Patent Application No. 2021-48834 filed on Mar. 23, 2021, the entire content of which is incorporated herein by reference.
The present disclosure relates to a back door and a rear window glass.
Some vehicles such as hatchback motor vehicles employ resinous back doors. In this case, a configuration is known in which a reinforce such as a metallic reinforcing frame is disposed in the periphery of an opening of the back door in order to heighten the rigidity of the back door. There are cases where a conductor such as a defogger or an antenna is disposed on the rear window glass to be attached to a back door. A configuration for use in such a rear window glass to be attached to a back door is known in which an auxiliary element which has branched off from the defogger is caused to achieve capacitive coupling with a metallic reinforcing frame grounded to the metallic body, thereby enabling the antenna to receive FM radio broadcast waves with high gain (see, for example Patent Document 1).
However, since reinforces vary in shape and size depending on the constitutions, there are cases where sufficient antenna gain is not obtained even after antenna tuning, depending on the shape of the reinforce, etc.
The present disclosure provides a back door and a rear window glass which are equipped with an antenna that attains relatively high antenna gain.
The present disclosure provides a back door including an opening, the back door including:
a resinous outer panel;
a resinous inner panel;
a metallic reinforce disposed between the outer panel and the inner panel; and
a rear window glass covering the opening, in which the rear window glass includes:
a defogger including a first bus bar that extends in an upper-lower direction, a second bus bar that is disposed apart from the first bus bar in a horizontal direction and extends in the upper-lower direction, and a plurality of heating wires that connect the first bus bar to the second bus bar;
an auxiliary element connected to the defogger; and
an antenna disposed so as to be surrounded by the defogger and the auxiliary element.
The present disclosure further provides a rear window glass capable of being attached to a resinous back door including a metallic reinforce such that the rear window glass covers an opening formed in the back door,
the rear window glass including:
a defogger including a first bus bar that extends in a first direction, a second bus bar that is disposed apart from the first bus bar in a second direction perpendicular to the first direction and extends in the first direction, and a plurality of heating wires that connect the first bus bar to the second bus bar;
an auxiliary element connected to the defogger; and
an antenna disposed so as to be surrounded by the defogger and the auxiliary element.
The present disclosure can provide a back door and a rear window glass which are equipped with an antenna that attains relatively high antenna gain.
Embodiments of the present disclosure are explained below by reference to the drawings. For an easier understanding, the scales of portions or parts in the drawings may differ from actual ones. Directions such as parallel, perpendicular, orthogonal, horizontal, vertical, upper-lower, and right-left directions are allowed to deviate to such a degree as not to impair the effects of the embodiments. The shape of a corner portion is not limited to a right angle and may be arched. The terms “X-axis direction”, “Y-axis direction”, and “Z-axis direction” respectively mean a direction parallel with the X axis, a direction parallel with the Y axis, and a direction parallel with the Z axis. The X-axis direction, the Y-axis direction, and Z-axis direction are orthogonal to each other. The terms “XY plane”, YZ plane”, and “ZX plane” respectively mean a virtual plane parallel with both the X-axis direction and the Y-axis direction, a virtual plane parallel with both the Y-axis direction and the Z-axis direction, and a virtual plane parallel with both the Z-axis direction and the X-axis direction.
Incidentally,
The outer panel 12 and the inner panel 13 are molded, for example, from a synthetic resin such as polypropylene or the like. The outer panel 12 is disposed on the outer side (more specifically on the vehicle rear side) of the inner panel 13.
The reinforce 14 is a metallic member to reinforce the back door 100 so as to improve the rigidity of the back door 100. The reinforce 14 is attached to either or both of the inner panel 13 and the outer panel 12 so that some or all of the opening 11 is surrounded by the reinforce 14. In the example illustrated in
The reinforce 14 is constituted of one or a plurality of members. In the example illustrated in
In the examples illustrated in
Likewise, in the example illustrated in
The rear window glass 15 is a window glass attached to the resinous back door 100 so as to cover the opening 11 formed in the back door 100. The rear window glass 15 is attached to the inner panel 13 on the outer side (in this example, on the positive side in Z-axis direction) thereof.
The rear window glass 15 includes a defogger 20, an antenna 40, and an auxiliary element 30.
The defogger 20 is a conductor pattern of the electric heating type to defog the rear window glass 15 upon voltage application thereto. The defogger 20 includes a plurality of heating wires 23 extending in the right-left direction (horizontal direction) of the rear window glass 15 and a plurality of bus bars 21 and 22 which is configured to feed electricity to the plurality of heating wires 23. The plurality of heating wires 23 are heater wires which extend side by side with each other in the right-left direction (horizontal direction) of the rear window glass 15 and which connect the first bus bar 21 to the second bus bar 22.
The first bus bar 21 is a strip electrode extending in the upper-lower direction from an upper end 21a to a lower end 21b, and is wider than each of the heating wires 23. The second bus bar 22 is a strip electrode disposed apart from the first bus bar 21 in the horizontal direction and extending in the upper-lower direction from an upper end 22a to a lower end 22b, and is wider than each of the heating wires 23. Upon voltage application between the bus bars 21 and 22, the plurality of heating wires 23 heat up due to the electricity and, hence, the rear window glass 15 is defogged.
The antenna 40 is a conductor disposed so as to be surrounded by the defogger 20 and the auxiliary element 30. In the example illustrated in
The antenna 40 is formed so as to be capable of sending/receiving (sending or receiving or both) radio waves in a predetermined frequency band F1, and resonates at frequencies in the frequency band F1. The antenna 40 has a shape suitable for sending/receiving radio waves in a very high frequency (VHF) band with frequencies of 30-300 MHz. Among frequency bands included in the VHF band are an FM broadcast frequency band (76-108 MHz), DAB Band III (174-240 MHz), etc. The shape of the antenna 40 may be one capable of sending/receiving radio waves in a ultra-high frequency (UHF) band with frequencies of 300 MHz to 3 GHz. The antenna 40 may also be a 4GLTE antenna or a 5G (sub6) antenna, which can send/receive radio waves in a 3-6 GHz frequency band.
The auxiliary element 30 is a wire conductor connected to the defogger 20. In the example illustrated in
The auxiliary element 30 has a first element end 61, at which the auxiliary element 30 is connected to the defogger 20, and a second element end 62, at which the auxiliary element 30 is connected to the defogger 20. The auxiliary element 30 is an element ranging from the first element end 61 to the second element end 62 and helps to increase the antenna gain of the antenna 40.
The auxiliary element 30 has an intermediate portion 60 which includes a point where the auxiliary element 30 intersects a center line 16 of the rear window glass 15 or defogger 20. The intermediate portion 60 is a portion of the auxiliary element 30 which lies between the first element end 61 and the second element end 62. The center line 16 is a virtual line extending in the upper-lower direction and, in particular, corresponds to the axis of symmetry of the rear window glass 15 or defogger 20 which is symmetric with respect to a line in a plan view. The auxiliary element 30 may be or may not be symmetric with respect to the center line 16. In the example illustrated in
In the first embodiment illustrated in
The auxiliary element 30 has a conductor portion extending, for example, along the reinforce 14. The conductor portion extending along the reinforce 14 is a portion extending parallel (or approximately parallel) with a surface portion or peripheral portion of the reinforce 14 in a plan view of the rear window glass 15. More specifically, that conductor portion is a portion extending parallel (or approximately parallel) with a direction in which the reinforce 14 extends.
The auxiliary element 30, due to the adjacent portions thereof which are adjacent to the reinforce 14, achieves capacitive coupling with the reinforce 14. The term “adjacent portion” means an element portion of the auxiliary element 30 which is apart from the reinforce 14 at such a distance that the element portion can achieve capacitive coupling with the reinforce 14. The distance that renders capacitive coupling possible is, for example, longer than 0 mm and 50 mm or shorter, and may be longer than 0 mm and 30 mm or shorter. In the example illustrated in
In the example illustrated in
In the first embodiment illustrated in
Consequently, the antenna 40 not only by itself receives radio waves in the frequency band F1 but also can acquire, through the heating wire 23a of the defogger 20, radio waves in the frequency band F1 received by the first dipole antenna 71, resulting in an improvement in antenna gain in the frequency band F1. Furthermore, the antenna 40 can acquire, through the heating wire 23a of the defogger 20, radio waves in the frequency band F1 received by the second dipole antenna 72, resulting in a further improvement in antenna gain in the frequency band F1.
As described above, the first embodiment illustrated in
The antenna 40 includes a feeding portion 41 and an antenna element 42 connected to the feeding portion 41. The antenna element 42 includes an element portion 42a which achieves capacitive coupling with the defogger 20. Due to the inclusion of this element portion 42a, the antenna 40 can efficiently acquire radio waves in the frequency band F1 received by the first dipole antenna 71 and radio waves in the frequency band F1 received by the second dipole antenna 72, through the heating wire 23a of the defogger 20. Thus, the antenna gain in the frequency band F1 improves still further. In the example illustrated in
The received signals obtained via the antenna 40 are taken out through the feeding portion 41. The signals taken out through the feeding portion 41 are transmitted to an input unit of an amplifier (not illustrated) via an electroconductive member conductively connected to the feeding portion 41. Specific examples of the electroconductive member include feeding lines such as AV wires and coaxial cables. The amplifier is configured to amplify the signals taken out through the feeding portion 41 and outputs the amplified signals to a signal processing circuit (not illustrated) mounted on the vehicle.
In the case of using a coaxial cable as a feeding line, the core wire (inner conductor) of the coaxial cable is connected to the feeding portion 41 and the outer conductor of the coaxial cable is connected to the vehicle body or to a ground (vehicle body ground) such as a metallic portion electrically connected to the vehicle body. The metallic portion electrically connected to the vehicle body may be, for example, the reinforce 14. A connector for connecting the amplifier to the feeding portion 41 may be used. This connector is mounted, for example, in the feeding portion 41. The amplifier may be mounted in the connector. The antenna 40 may be what is called a monopole antenna, which has only one feeding portion 41, or may be a dipole antenna that has two feeding portions 41, one of which is connected to the core wire of a coaxial cable and the other is connected to the outer conductor of the coaxial cable.
In
A wavelength in air of radio waves in a given frequency band F1 which are to be received by the antenna 40 is expressed by k, and a wavelength shortening ratio of the rear window glass 15 is expressed by k. In cases when the conducting route CL1 and/or the conducting route CL2 has a length L of 0.90×λ/2×k or longer and 1.10×λ/2×k or shorter, antenna gain in the frequency band F1 is improved. From the standpoint of improving the antenna gain in the frequency band F1, the length L of the at least one conducting route is preferably 0.92×λ/2×k or longer and 1.08×λ/2×k or shorter, more preferably 0.94×λ/2×k or longer and 1.06×λ/2×k or shorter.
In
In cases when the first adjacent portion 31 includes a first horizontal adjacent portion 35, which extends in the horizontal direction along the upper left-hand reinforce portion 14Ab extending in the horizontal direction, then the antenna gain in sending/receiving horizontally polarized waves in the frequency band F1 is improved. Likewise, in cases when the second adjacent portion 32 includes a second horizontal adjacent portion 36, which extends in the horizontal direction along the upper right-hand reinforce portion 14Bb extending in the horizontal direction, then the antenna gain in sending/receiving horizontally polarized waves in the frequency band F1 is improved. The first horizontal adjacent portion 35 is an example of a horizontal conductor portion extending along a horizontal reinforce portion, and is adjacent to the upper left-hand reinforce 14Ab. The second horizontal adjacent portion 36 is an example of a horizontal conductor portion extending along a horizontal reinforce portion, and is adjacent to the upper right-hand reinforce 14Bb.
In cases when the first adjacent portion 31 overlies the left-hand reinforce 14A in a plan view of the rear window glass 15, this facilitates capacitive coupling with the left-hand reinforce 14A in the Z-axis direction. Thus, the coupling strength increases, resulting in an improvement in antenna gain in the frequency band F1. Likewise, in cases when the second adjacent portion 32 overlies the right-hand reinforce 14B in the plan view of the rear window glass 15, this facilitates capacitive coupling with the right-hand reinforce 14B in the Z-axis direction. Thus, the coupling strength increases, resulting in an improvement in antenna gain in the frequency band F1.
In cases when the conducting route ranging from the first vertical adjacent portion 33 to the lower end 21b has a length LQ1 of 0.95×λ/4×k or longer and 1.05×λ/4×k or shorter, then the antenna gain in sending/receiving vertically polarized waves in the frequency band F1 is improved. That is, in cases when the length (LQ1) over which the first vertical adjacent portion 33 and the first bus bar 21 extend in the upper-lower direction (Y-axis direction) along the left-hand reinforce 14A is within the aforementioned range, then the antenna gain for vertically polarized waves in the frequency band F1 is improved. From the standpoint of improving the antenna gain in sending/receiving vertically polarized waves in the frequency band F1, the length LQ1 is preferably 0.96×λ/4×k or longer and 1.04×λ/4×k or shorter, more preferably 0.97×λ/4×k or longer and 1.03×λ/4×k or shorter. Incidentally, the starting point of the length LQ1 may be any point within the first vertical adjacent portion 33. The ending point of the length LQ1 need not be the lower end 21b of the first bus bar 21 and may be any point on the heating wire 23f which, among the plurality of heating wires 23, is most apart from the first adjacent portion 31.
In cases when the conducting route ranging from the second vertical adjacent portion 34 to the lower end 22b has a length LQ2 of 0.95×λ/4×k or longer and 1.05×λ/4×k or shorter, then the antenna gain in sending/receiving vertically polarized waves in the frequency band F1 is improved. That is, in cases when the length (LQ2) over which the second vertical adjacent portion 34 and the second bus bar 22 extend in the upper-lower direction (Y-axis direction) along the right-hand reinforce 14B is within the aforementioned range, then the antenna gain for vertically polarized waves in the frequency band F1 is improved. From the standpoint of improving the antenna gain in sending/receiving vertically polarized waves in the frequency band F1, the length LQ2 is preferably 0.96×λ/4×k or longer and 1.04×λ/4×k or shorter, more preferably 0.97×λ/4×k or longer and 1.03×λ/4×k or shorter. Incidentally, the starting point of the length LQ2 may be any point within the second vertical adjacent portion 34. The ending point of the length LQ2 need not be the lower end 22b of the second bus bar 22 and may be any point on the heating wire 23f which, among the plurality of heating wires 23, is most apart from the second adjacent portion 32.
In cases when the defogger 20 includes one or more short-circuiting wires which short-circuit the plurality of heating wires 23 in the upper-lower direction, the antenna gain in the frequency band F1 is improved. In the example illustrated in
Here, in cases when a route ranging from the intermediate portion 60 to any point on the heating wire 23f via the first adjacent portion 31 and the short-circuiting wire 24 is referred to as route L3 and when the route L3 has a length of 0.90×λ/2×k or longer and 1.10×λ/2×k or shorter, then the antenna gain in the frequency band F1 is improved. Any point on the heating wire 23f is an example of a route end on a heating wire which, among the plurality of heating wires 23, is most apart from the first adjacent portion 31. Incidentally, in the case where the lower end 24b of the short-circuiting wire 24 does not lie on the heating wire 23f, the route end of the route L3 is not any point on the heating wire 23f and may be the lower end 24b. The lower end 24b in this case is an example of a wire end which, among the wire ends of the short-circuiting wire 24, is most apart from the first adjacent portion 31. Especially in the case where the first vertical adjacent portion 33 of the auxiliary element 30 is connected to a point nearer to the short-circuiting wire 24 than to the first bus bar 21, then high-frequency current flows through the route L3 in an increased amount and the route L3, via the short-circuiting wire 24, functions as a dipole antenna together with the first dipole antenna of the route L1. Also in this case, the antenna 40 has an increased antenna gain due to these dipole antennas.
Likewise, in cases when a route ranging from the intermediate portion 60 to any point on the heating wire 23f via the second adjacent portion 32 and the short-circuiting wire 25 is referred to as route L3 and when the route L3 has a length of 0.90×λ/2×k or longer and 1.10×λ/2×k or shorter, then the antenna gain in the frequency band F1 is improved. Any point on the heating wire 23f is an example of a route end on a heating wire which, among the plurality of heating wires 23, is most apart from the second adjacent portion 32. Incidentally, in the case where the lower end 25b of the short-circuiting wire 25 does not lie on the heating wire 23f, the route end of the route L3 is not any point on the heating wire 23f and may be the lower end 25b. The lower end 25b in this case is an example of a wire end which, among the wire ends of the short-circuiting wire 25, is most apart from the second adjacent portion 32. Especially in the case where the second vertical adjacent portion 34 of the auxiliary element 30 is connected to a point nearer to the short-circuiting wire 25 than to the second bus bar 22, then high-frequency current flows through the route L3 in an increased amount and the route L3, although including the short-circuiting wire 25, functions as a dipole antenna together with the second dipole antenna of the route L2. Also in this case, the antenna 40 has an increased antenna gain due to these dipole antennas.
From the standpoint of improving the antenna gain in the frequency band F1, the length of the route L3 is preferably 0.92×λ/2×k or longer and 1.08×λ/2×k or shorter, more preferably 0.94×λ/2×k or longer and 1.06×λ/2×k or shorter.
The horizontal-direction width of the defogger 20 (distance between the first bus bar 21 and the second bus bar 22) is expressed by W. In cases when the first element end 61, where the auxiliary element 30 is connected to the defogger 20, lies in the range of from a horizontal-direction end (first bus bar 21) of the defogger 20 to a point being 0.3×W away in a horizontal direction from the horizontal-direction end, the antenna gain in the frequency band F1 is improved. From the standpoint of improving the antenna gain in the frequency band F1, the first element end 61 lies preferably in the range of from the first bus bar 21 to a point being 0.2×W away in the horizontal direction from the first bus bar 21, more preferably in the range of from the first bus bar 21 to a point being 0.1×W away in the horizontal direction from the first bus bar 21, and still more preferably is connected to the first bus bar 21.
Likewise, in cases when the second element end 62, where the auxiliary element 30 is connected to the defogger 20, lies in the range of from a horizontal-direction end (second bus bar 22) of the defogger 20 to a point being 0.3×W away in the horizontal direction from the horizontal-direction end, the antenna gain in the frequency band F1 is improved. From the standpoint of improving the antenna gain in the frequency band F1, the second element end 62 lies preferably in the range of from the second bus bar 22 to a point being 0.2×W away in the horizontal direction from the second bus bar 22, more preferably in the range of from the second bus bar 22 to a point being 0.1×W away in the horizontal direction from the second bus bar 22, and still more preferably is connected to the second bus bar 22. Furthermore, in cases when the auxiliary element 30 is connected to the defogger 20 at points near the first bus bar 21 and the second bus bar 22, then the first vertical adjacent portion 33 and the second vertical adjacent portion 34 of the auxiliary element 30 are disposed respectively in left-hand and right-hand end areas of the rear window glass 15, making the auxiliary element 30 less apt to narrow the view.
In cases when the minimum distance d between the antenna 40 and the auxiliary element 30 is 10 mm or longer, the antenna gain in the frequency band F1 is improved. In the example illustrated in
The auxiliary element 30 includes a first auxiliary element 38 and a second auxiliary element 39, which face each other with the gap 37 therebetween. Although the auxiliary element 30 has the gap 37 therein, the antenna 40 is disposed so as to be surrounded by the defogger 20 and the auxiliary element 30. Incidentally, the configuration where “the antenna 40 is disposed so as to be surrounded by the defogger 20 and the auxiliary element 30” encompasses not only a configuration where the defogger 20 and the auxiliary element 30 form a closed loop but also a configuration where the gap 37 is present between a plurality of the auxiliary elements like this embodiment, for example.
Consequently, like the first embodiment, the second embodiment makes it possible to obtain a back door and a rear window glass which are equipped with an antenna attaining relatively high antenna gain. Even in cases when the configuration illustrated in
In cases when the gap 37 has a length e of 300 mm or less, the antenna gain in the frequency band F1 is improved. From the standpoint of improving the antenna gain in the frequency band F1, the length of the gap 37 is preferably 200 mm or less, more preferably 100 mm or less, still more preferably 50 mm or less, especially preferably 20 mm or less, most preferably 10 mm or less.
In the example illustrated in
In
In the cases of “a=80 mm” and “a=260 mm”, the first element end 61 lies in the range of from the first bus bar 21 to a point being 0.3×W away from the first bus bar 21 and the second element end 62 lies in the range of from the second bus bar 22 to a point being 0.3×W away from the second bus bar 22. In the case of “a=0 mm”, the first element end 61 is connected to the first bus bar 21 and the second element end 62 is connected to the second bus bar 22. In particular, under the conditions of “a=80 mm” and “a=0 mm”, the auxiliary element 30 is disposed so as to overlie at least the left-hand reinforce portion 14Aa and the right-hand reinforce portion 14Ba in a plan view of the rear window glass 15 to achieve capacitive coupling with each of these reinforce portions.
The wavelength shortening ratio k of the rear window glass 15 is taken as 0.7, and the wavelength λ in air of radio waves in an FM broadcast frequency band F1 (76-108 MHz) is in the range of 2,776-3,945 mm. Hence, (λ/2)×k is in the range of 972-1,381 mm and (λ/4)×k is in the range of 486-690 mm. In the cases of “a=80 mm” and “a=0 mm”, “(λ/2) k”, which is included in the expressions indicating preferred ranges of the conducting route CL1 and conducting route CL2, was regulated to 972-1,381 mm and “(λ/4)×k”, which is included in the expressions indicating preferred ranges of the conducting route LQ1 and conducting route LQ2, was regulated to 486-690 mm. Furthermore, in the case of “a=260 mm”, the length of the route L3 was regulated to a value in the range of 972-1,381 mm, which corresponds to (λ/2)×k.
From the data shown in
REF1: −22.4 (dBd)
REF2: −14.7 (dBd)
a=260 mm: −19.1 (dBd)
a=80 mm: −14.0 (dBd)
a=0 mm: −13.4 (dBd)
As demonstrated above, the cases where the back doors each included an auxiliary element 30 had improved average antenna gains in the FM broadcast frequency band, as compared with REF1, in which the back door included a reinforce 14 but included no auxiliary element 30. The obtained results indicate that the case in which the first element end 61 was connected to the first bus bar 21 and the second element end 62 was connected to the second bus bar 22 was the highest in average antenna gain.
In measurements, the results of which are shown in
Length of the antenna element 42: 280 mm (80 mm (vertical)+200 mm (horizontal))
Spacing between the antenna element 42 and the heating wire 23a: 5 mm
Horizontal distance from the center line 16 to the short-circuiting wire 24: 300 mm
Horizontal distance from the center line 16 to the short-circuiting wire 25: 295 mm
Minimum distance between the auxiliary element 30 and the reinforce 14: 12.6 mm
W: 1,138 mm
d: 30 mm
From the data shown in
REF1: −22.4 (dBd)
REF2: −14.7 (dBd)
d=10 mm: −15.6 (dBd)
d=30 mm: −14.0 (dBd)
d=50 mm: −13.7 (dBd)
That is, the obtained results show that the longer the minimum distance d between the antenna 40 and the auxiliary element 30, the higher the average antenna gain.
In making measurements, the results of which are shown in
From the data shown in
REF1: −22.4 (dBd)
REF2: −14.7 (dBd)
e=0 mm: −14.0 (dBd)
e=10 mm: −15.5 (dBd)
e=20 mm: −15.5 (dBd)
e=100 mm: −15.4 (dBd)
e=200 mm: −16.1 (dBd)
As demonstrated above, even in the cases where the auxiliary element 30 has a gap 37, average antenna gains are higher than REF1. In making measurements, the results of which are shown in
While embodiments have been described above, the present disclosure is not limited to the embodiments and can be variously modified or improved, for example, by combining any of the embodiments with some or all of another embodiment or replacing some of any of the embodiments by some or all of another embodiment.
For example, an “end” of an element may be a starting point or ending point of an extension of the element, or may be a near-starting-point portion or near-ending-point portion which is a conductor portion before the starting point or ending point. Furthermore, an “end” of an element may have a bend or a fold. The term “end” can mean “one end”, “the other end”, “leading end”, “trailing end”, or “open end”. Elements may be connected to each other so that the connected portions have a curvature.
The antenna element and the electrode (feeding portion) are each formed, for example, by printing a paste containing an electroconductive metal (e.g., a silver paste) on a surface of a window glass, the surface being to face an inside of vehicles, and baking the paste. However, methods for forming the antenna element and electrode are not limited to the method. For example, the antenna element or the electrode may be formed by disposing a wire-shaped or foil-shaped object including an electroconductive material such as copper on a surface of a window glass, the surface being to face the inside of vehicles, or a surface of a window glass, the surface being to face the outside of vehicles. Alternatively, the antenna element or the electrode may be adhered to the window glass with an adhesive or the like, or may be disposed in an inner portion of the window glass itself.
The shape of the electrode (feeding portion) is preferably a quadrilateral shape such as a square, approximately square, rectangular, or approximately rectangular shape, or a polygonal shape, from the standpoint of mounting. The shape of the electrode may be a circular shape such as a circle, an approximate circle, an ellipse, or an approximate ellipse.
Moreover, a configuration may be employed in which a conductor layer for forming the antenna element and/or the electrode is disposed inside a synthetic-resin film or on a surface thereof and the synthetic-resin film with the conductor layer is disposed on a surface of window glass, the surface being to face the inside of vehicles, or a surface of window glass, the surface being to face the outside of vehicles. Furthermore, a configuration may be employed in which a flexible circuit board having the antenna element and/or the electrode formed thereon is disposed on a surface of window glass, the surface being to face the inside of vehicles, or a surface of window glass, the surface being to face the outside of vehicles.
Number | Date | Country | Kind |
---|---|---|---|
2021-048834 | Mar 2021 | JP | national |