JP6221779B2 - Glass antenna - Google Patents

Description

  The present invention relates to a glass antenna disposed on the surface of a glass plate, and more particularly to an antenna that receives a plurality of frequency bands.

  In countries around the world, radio and television broadcast frequencies and frequencies used for remote keyless entry (RKE) differ depending on the country and region, and therefore it is necessary to develop antennas with different element lengths for each destination. However, in order to develop many types of antennas, a large number of work steps are required, and thus antennas corresponding to a plurality of bands are desired. For example, the frequency used for remote keyless entry is 315 MHz in Japan and the United States, and 433.92 MHz in Europe. If good sensitivity cannot be obtained in a plurality of bands, it is necessary to adjust the length of the element for each destination.

  As an antenna for obtaining good sensitivity at such a plurality of frequencies, Patent Document 1 describes a typical dual-frequency switching type antenna. Since the antenna described in Patent Document 1 receives two radio waves in the 800 MHz band and the 1500 MHz band, the antenna has two elements having a length suitable for each frequency, and the two elements are bifurcated or V-shaped. Connected in a shape.

JP-A-6-291530

  In the high frequency band targeted by the antenna described in Patent Document 1, the antenna pattern can be reduced. However, in order to receive a relatively low frequency (315 MHz, 433.92 MHz) with high sensitivity like a remote keyless entry antenna, there is a problem that the antenna pattern becomes large.

  In general, the antenna pattern is arranged in a portion where the heating filament of the rear window defogger is not arranged or a portion which does not disturb the human visual field. For this reason, it is difficult to arrange a large conspicuous pattern on the glass plate.

  Therefore, an object of the present application is to provide a glass antenna that can obtain good reception performance in two frequency bands even if it is disposed in a narrow place of an automobile window glass.

  That is, this invention is a glass antenna arrange | positioned at the window glass for vehicles, Comprising: The electric power feeding part connected with a receiver, The 1st element extended from the said electric power feeding part, The said 1st element is the said electric power feeding. An overlap portion disposed at a predetermined interval along a second element that is not connected to the portion, and a non-overlap portion that is not along the second element, and the overlap portion and the non-overlap portion The length of each of the overlap portion and the non-overlap portion is adjusted so that one of the overlap portions is tuned in the first frequency band and the other is tuned in the second frequency band. It is an antenna.

  Further, the present invention is the glass antenna, wherein the second element is an element constituting an antenna different from the antenna provided with the first element.

  According to the present invention, the glass antenna is a UHF band signal receiving antenna, and the antenna having the second element is a medium wave AM broadcast receiving antenna. It is.

  Furthermore, the present invention is the glass antenna, wherein the first element is bent halfway.

  Furthermore, the present invention is a glass antenna characterized in that a portion between the portion where the first element is bent and the power feeding portion is constituted by a plurality of filaments.

In the present invention, the wavelength of the center frequency of the first frequency band is λ ₁ , the wavelength of the center frequency of the second frequency band is λ ₂ , and the wavelength reduction rate of the window glass is α , the length of the overlapping portion is substantially αλ _1/2, a glass antenna, wherein the length of the non-overlapping portion is substantially αλ _2/2.

  Furthermore, the present invention is the glass antenna characterized in that the first frequency band is lower than the second frequency band.

  Further, the present invention is the glass antenna, wherein the center frequency of the first frequency band is about 315 MHz, and the center frequency of the second frequency band is about 433 MHz.

  Furthermore, the present invention is the glass antenna characterized in that an interval between the first element and the second element in the overlap portion is 10 mm or less.

  In the present invention, when the glass antenna is attached to an automobile, the first element is disposed at a position not less than 5 mm and not more than 10 mm from an edge of the body flange of the automobile. The glass antenna is characterized in that the first element is capacitively coupled.

  According to the representative embodiment of the present invention, high sensitivity can be obtained in a plurality of frequency bands.

The front view of the antenna pattern of 1st Example of this invention. The front view of the antenna pattern of 2nd Example of this invention. The front view of the antenna pattern of 3rd Example of this invention. The front view of the antenna pattern of 4th Example of this invention. The front view of the antenna pattern of 5th Example of this invention. The frequency characteristic figure of the antenna of 5th Example of this invention. The frequency characteristic figure of the antenna of 5th Example of this invention.

  1 to 5 are views of a glass antenna according to an embodiment of the present invention as viewed from the vehicle interior side.

  As shown in FIG. 1, a glass antenna 100 according to an embodiment of the present invention is provided on a rear glass of an automobile, and includes a power feeding unit 2 and a first element 1 extending from the power feeding unit 2. A part of the first element 1 is provided with a second element 52F adjacent thereto. For this reason, the 1st element 1 can be divided into the overlap part 1A in which the 2nd element 52F is arrange | positioned close, and the non-overlap part 1B in which the 2nd element 52F is not arrange | positioned close. .

  The power feeding unit 2 is connected to a reception amplifier 6 by a connection line (for example, AV electric wire) 5, and the reception amplifier 6 is connected to a receiver by a high frequency cable (for example, a coaxial cable). The receiving amplifier 6 is connected to the ground (vehicle body).

  As shown in FIG. 1, the second element 52F may be a conductor wire that does not constitute another antenna, or as shown in FIG. 2, the second element 52F may be a part of another antenna.

  As shown in FIGS. 3 and 5, the first element 1 may have a bent portion 3, and the non-overlap portion 1 </ b> B may be bent at the bent portion 3.

  As shown in FIG. 4, the second element 52 </ b> F may be bent along the first element 1 in response to the first element 1 being bent.

  Moreover, as shown in FIG. 5, the 1st element 1 may connect between the bending part 3 and the electric power feeding part 2 with a several conductive wire.

  Further, as shown in FIG. 5, the first element 1 is disposed close to (for example, parallel to, 5 mm apart) the body flange 82 of the vehicle body, and the antenna 100 and the body flange 82 (that is, ground) are connected. Capacitive coupling may be used.

  In the antenna according to the embodiment of the present invention, the pattern is printed at a predetermined position on the indoor side of the window glass plate with a conductive ceramic paste at a width of about 0.7 mm, dried, and then baked in a heating furnace. Formed. Alternatively, an antenna may be formed using a conductive pattern formed on a resin film that transmits light, and attached to a glass plate.

  As described above, the embodiment in which the antenna is provided on the rear glass 81 of the automobile has been described with respect to the embodiment of the present invention. However, the antenna according to the embodiment of the present invention may be provided in another location (for example, a windshield and a side glass).

  The length of each element of the antenna according to the embodiment of the present invention is adjusted to a length suitable for receiving a UHF band signal used in remote keyless entry, as will be described later in each example. Note that an antenna suitable for receiving signals in other frequency bands can be used.

  Next, the effect | action of the glass antenna of embodiment of this invention is demonstrated.

  The antenna of the present embodiment includes a power feeding unit 2 and a first element 1 extending from the power feeding unit 2, and the first element 1 has a predetermined element along a second element 52 </ b> F that is not connected to the power feeding unit 2. It includes an overlap portion 1A in which the second element 52F is disposed at a distance, and a non-overlap portion 1B that is not along the second element 52F. Then, the first frequency band can be favorably received by one of the overlap part 1A and the non-overlap part 1B, and the overlap part 1A and the non-overlap part 1B can be favorably received by the other one. Adjust the length of each. For this reason, the antenna which can receive two frequency bands with high sensitivity and can be arranged in a narrow place can be configured.

  That is, the antenna according to the present embodiment has a simple configuration in which the main body includes only the power feeding unit 2 and the first element 1, but the second element 52 </ b> F is disposed along a part of the first element 1. The length of the overlap portion 1A and the length of the non-overlap portion 1B are appropriately adjusted so that the two frequency bands can be received with high sensitivity.

  In addition, the second element 52F may be an element that constitutes a part or all of an antenna different from the antenna provided with the first element 1, so that the element of the other antenna can be used even in a place where another antenna is disposed. By using it, the antenna of this embodiment can obtain good reception performance at two frequencies. Moreover, since the antenna of this embodiment may be arrange | positioned adjacent to the said another antenna, it can also be arrange | positioned in a narrow place.

  Moreover, since the 1st element 1 is bent in the middle (bending part 3), another antenna is attached and the antenna of this embodiment can be attached also to the glass in which only a narrow place remains. For example, when the antenna of the present embodiment is arranged in a narrow place, even if the overlap portion can be set to an appropriate length, if the element is stretched straight, it may protrude from the glass plate or the corner portion of the body flange. Due to interference, the non-overlap portion 1B may not be able to have an appropriate length. Therefore, the non-overlap portion 1B can be lengthened by bending the first element 1.

  Moreover, the electric power feeding part 2 may be arrange | positioned in the position close | similar to the position near the side of the glass for motor vehicles. For this reason, as shown in FIG. 4, the second element 52F is bent along the first element 1 and the lengths of the bent portions of the first element 1 and the second element 52F are adjusted. The position of the power feeding unit 2 on the plate can be adjusted.

  Moreover, since the bending part 3 of the 1st element 1 and the electric power feeding part 2 are connected by a some filament, a sensitivity can be improved.

  In addition, since the interval between the first element 1 and the second element 52F in the overlap portion 1A is set to 10 mm or less, the first element 1 and the second element 52F are strongly coupled to each other, and good sensitivity is obtained in two frequency bands. It will be easier to get.

  Further, since the first element 1 is disposed at a position 5 mm to 10 mm away from the body flange 82, high sensitivity can be obtained in a desired frequency band.

  Hereinafter, various embodiments of the present invention will be described.

<Example 1>
FIG. 1 is a front view of a glass antenna provided on a rear glass of an automobile, showing an antenna pattern of a first embodiment of the present invention.

  The glass antenna 100 according to the first embodiment includes a power feeding unit 2 and a first element 1 extending from the power feeding unit 2 in a substantially horizontal direction (rightward). A part of the first element 1 is arranged with the second element 52F in close proximity (for example, parallel at an interval of 10 mm). For this reason, the 1st element 1 can be divided into the overlap part 1A in which the 2nd element 52F is arrange | positioned close, and the non-overlap part 1B in which the 2nd element 52F is not arrange | positioned close. .

  The second element 52F of the first embodiment is a conductor wire that does not constitute another antenna and is not connected to the ground.

The length of each element of the glass antenna of the first embodiment is suitable for receiving signals in frequency band 1 (wavelength of central frequency = λ ₁ ) and frequency band 2 (wavelength of central frequency = λ ₂ ). The length of the first element 1 is 605 mm, the length of the overlap portion 1A is 370 mm, and the length of the non-overlap portion 1B is 235 mm.

  In the first embodiment, since one first element 1 is composed of the overlap portion 1A and the non-overlap portion 1B, an antenna capable of receiving two frequency bands with high sensitivity even in a narrow place can be configured. it can.

<Example 2>
FIG. 2 is a front view of a glass antenna provided on a rear glass of an automobile, showing an antenna pattern according to a second embodiment of the present invention.

  The glass antenna of the second embodiment differs from the first embodiment in that the second element 52F constitutes a part of another antenna (second antenna 50).

  As shown in FIG. 2, the second antenna 50 includes a plurality of horizontal filaments 52, a plurality of vertical filaments 53 connecting the horizontal filaments 52, and a second power feeding unit 54 provided at an end of the horizontal filament 52. Have. One of the horizontal filaments 52 (for example, the uppermost horizontal filament 52F) is disposed adjacent to the first element 1. As for the 2nd antenna 50, each filament is arrange | positioned in an area suitable in order to receive AM radio broadcast band (526.5-1606.5kHz).

  Since the configurations of the second embodiment other than those described above are the same as those of the first embodiment, the same reference numerals are given and description thereof is omitted.

  In the second embodiment, even in a narrow place where another antenna is arranged, good reception performance can be obtained at two frequencies by using the element 52F of the other antenna.

<Example 3>
FIG. 3 is a front view of a glass antenna provided on a rear glass of an automobile, showing an antenna pattern according to a third embodiment of the present invention.

  The glass antenna of the third embodiment is different from the second embodiment in that the first element 1 is bent. That is, the first element 1 of the third embodiment extends upward from the power feeding portion 2, bends in the lateral direction (rightward) at the bending portion 3 in the non-overlap portion 1B, and approaches the second element 52F. And stretch.

The length of each element of the glass antenna of the third embodiment is adjusted to a length suitable for receiving the band of the remote keyless entry, the length of the first element 1 is 605 mm, and the overlap portion 1A The length is 370 mm, and the length of the non-overlap portion 1B is 235 (160 + 75) mm. That is, when the wavelength shortening rate α of the rear glass 81 is 0.7 and the center frequency (wavelength = λ ₁ ) of the RKE band in Japan and the United States is 315 MHz, the length of the overlap portion 1A is approximately αλ _1/2. Become. Also, if 433.92MHz the center frequency (wavelength = lambda ₂₎ of RKE band in Europe, the length of the non-overlapping portion 1B is substantially αλ _2/2.

  In addition, although the overlap part 1A was adjusted to the low frequency band and the non-overlap part 1B was adjusted to the high frequency band, the overlap part 1A was adjusted to the high frequency band and the non-overlap part 1B was set to the low frequency band. You may adjust.

  Since the configuration of the third embodiment other than that described above is the same as that of the second embodiment, the same reference numerals are given and description thereof is omitted.

  In the third example, since the first element 1 is bent at the bent portion 3, another antenna is attached, and the antenna of this embodiment can be attached to glass where only a narrow place remains. Good reception performance can be obtained at two frequencies.

<Example 4>
FIG. 4 is a front view of a glass antenna provided on a rear glass of an automobile, showing an antenna pattern according to a fourth embodiment of the present invention.

  The glass antenna of the fourth embodiment is different from the third embodiment in that the second element 52F is bent. That is, the second element 52F of the fourth embodiment extends in the lateral direction (substantially horizontal) along the first element, is further bent along the bent first element 1, and is longitudinal (substantially vertical). Stretch to.

  Since the configurations of the fourth embodiment other than those described above are the same as those of the third embodiment, the same reference numerals are given and description thereof is omitted.

  In the fourth embodiment, since the second element 52F is arranged along the first element 1, the length of the bent portion of the first element 1 and the second element 52F is adjusted to adjust the length on the glass plate. The position of the power feeding unit 2 can be adjusted.

<Example 5>
FIG. 5 is a front view of a glass antenna provided on a rear glass 81 of an automobile, showing an antenna pattern according to a fifth embodiment of the present invention.

  In the glass antenna of the fifth embodiment, an antenna having a configuration similar to that of the glass antenna of the above-described embodiment is mounted as the fifth antenna 100, and further, the first antenna 10, the second antenna 50, the third antenna 60, and the first antenna. 4 antennas 70 are used. The fifth antenna 100 of the fifth embodiment is different from the glass antenna of the third embodiment in that the bent portion 3 and the power feeding portion 2 are connected by a plurality of conductive wires.

  The fifth antenna 100 includes a power feeding unit 2 and a first element 1 extending from the power feeding unit 2 in a substantially horizontal direction (rightward). A part of the first element 1 is arranged with the second element 52F in close proximity (for example, parallel at an interval of 10 mm). For this reason, the 1st element 1 can be divided into the overlap part 1A in which the 2nd element 52F is arrange | positioned close, and the non-overlap part 1B in which the 2nd element 52F is not arrange | positioned close. .

  Further, the first element 1 has two parallel conductor wires extending upward from the power feeding portion 2 and bent in the lateral direction (rightward) at the bent portion 3 in the non-overlap portion 1B. The second element 52F Stretched close to. That is, the bent portion 3 and the power feeding portion 2 are connected by two conductive wires. The number of conductors between the bent portion 3 and the power feeding portion 2 may be three or more.

  The second element 52F constitutes a part of the second antenna 50.

  Since the configuration of the fifth antenna 100 of the fifth embodiment other than the above is the same as that of the glass antenna of the third embodiment, description thereof will be omitted.

  Next, configurations other than the fifth antenna 100 in the glass antenna of the fifth embodiment will be described.

  The first antenna 10 includes a first power feeding unit 15, a horizontal first element 11, a horizontal second element, a vertical element 31, and auxiliary elements 12 and 13.

  The horizontal first element 11 is connected to the first power feeding unit 15 and extends in a substantially horizontal direction (left direction in the figure). The horizontal second element is connected to the first power feeding unit 15 and extends substantially in parallel with the horizontal first element 11 in the same direction as the horizontal first element 11 (right direction in the drawing). The horizontal second element is folded downward from the main body portion 21 extending from the first power feeding portion 15 and at the end of the main body portion 21, is substantially parallel along the main body portion 21, and approaches the first power feeding portion 15. And a folded portion 22 extending in the direction.

  The vertical element 31 extends from the first power feeding unit 15 in a direction different from the extending direction of the horizontal first element 11 and the extending direction of the horizontal second element. The auxiliary element 12 extends downward from the intersection between the vertical portion and the horizontal portion of the first element, and is then disposed substantially in parallel along the horizontal first element 11. Further, the auxiliary element 12 is arranged close to the defogger 90 (for example, 5 mm apart in parallel) so as to be capacitively coupled to the uppermost heating filament 91 of the defogger 90. The auxiliary element 13 extends rightward from the vertical portion of the first element, and is arranged substantially in parallel along the horizontal first element 11.

  The length of each element of the first antenna 10 is adjusted so as to suitably receive the FM radio broadcast band and the DAB band 3.

  The second antenna 50 includes a plurality of horizontal filaments 52, a plurality of vertical filaments 53 connecting the horizontal filaments 52, a second feeding unit 54 provided at an end of the horizontal filaments 52, and folded portions 56 and 57. Have. One of the horizontal filaments 52 is disposed between the auxiliary element 13 of the first antenna 10 and the folded portion 22. The folded portions 56 and 57 extend upward from the uppermost horizontal filament 52, are folded laterally, and extend close to the horizontal filament 52 (for example, 5 mm apart in parallel). The folded portions 56 and 57 are arranged close to the body flange 82 of the vehicle body (for example, 5 mm apart and in parallel), and the second antenna 50 and the body flange 82 (that is, ground) are capacitively coupled. Each filament of the second antenna 50 is adjusted to a length suitable for receiving the AM radio broadcast band (526.5 to 1606.5 kHz).

  The third antenna 60 is constituted by the filaments of the defogger 90, and the defogger 90 functions as a third antenna.

  The defogger 90 functioning as the third antenna 60 includes a pair of bus bars 93 provided on the left and right sides of the rear glass 81, a plurality of heating wires 91 (horizontal wires) connecting the two bus bars 93, and a plurality of heating wires. It has a vertical line 92 connecting the lines 91. The number of vertical filaments 92 may be one or more.

  The bus bar 93 is provided with a defogger coil 94 and a third power feeding unit 95. That is, one bus bar 93 is connected to the power source via the defogger coil 94, and the other bus bar 93 is connected to the ground via the defogger coil 94. The defogger coil 94 suppresses noise in the reception frequency band that flows into the third antenna 60 from the power source and the ground.

  The defogger coil 94 and the third power supply unit 95 are arranged at the center of the bus bar 93 with the defogger coil 94 on the upper side and the third power supply unit 95 on the lower side, but the positions where the defogger coil 94 and the third power supply unit 95 are arranged. Can be anywhere on the bus bar 93. Furthermore, the order (upper and lower positional relationship) in which the defogger coil 94 and the third power feeding unit 95 are arranged is not limited to that illustrated.

  The first antenna 10 and the third antenna 60 may constitute a diversity antenna, and at least one of the FM radio broadcast wave and the DAB band 3 broadcast wave may be diversity-received. In this case, when the third antenna 60 (defogger 90) receives the FM radio broadcast wave and the DAB band 3 broadcast wave, the power supply unit 95 is provided in the bus bar 93 far from the first antenna 10 (for example, on the right side). Good.

  Further, the first antenna 10 and the fourth antenna 70 may constitute a diversity antenna, and a DAB broadcast wave may be received with diversity.

  The third antenna 60 includes parallel auxiliary filaments 96, 97, 98 extending from the bus bar 93 and a fourth auxiliary element 89.

  The end portions of the parallel auxiliary filaments 96, 97, and 98 are located away from each other. Further, a part of the parallel auxiliary line 96 and a part of the parallel auxiliary line 97 are arranged in close proximity to each other so as to be along each other. Furthermore, a part of the parallel auxiliary line 97 and a part of the parallel auxiliary line 98 are arranged in close proximity to each other so as to be along each other. In this manner, since the two parallel auxiliary filaments 96, 97, and 98 are arranged so as to overlap, each parallel auxiliary filament is capacitively coupled at the end. In addition, it may be arrange | positioned so that not only a part of parallel auxiliary filament but almost all may mutually follow.

  The fourth auxiliary element 89 extends upward from the bus bar 93 on the right side (close to the fourth antenna 70), and bends and extends in the left direction. Note that the fourth auxiliary element 89 may extend from the outermost horizontal filament 91.

  The 4th antenna 70 is comprised by the 4th electric power feeding part 71, the some horizontal element 72, and the some vertical element 73, and is adjusted to the suitable length in order to receive TV broadcast band (470-770 MHz). In this case, a diversity antenna may be configured by the third antenna 60 and the fourth antenna 70 to receive the TV broadcast diversity.

  Each of the power feeding units 2, 15, 54, 71, and 95 is connected to a reception amplifier by a connection line (for example, an AV electric wire), and the reception amplifier is connected to a receiver by a high-frequency cable (for example, a coaxial cable). The receiving amplifier is connected to the ground (vehicle body).

  The fifth antenna 100 of the fifth embodiment may use the glass antenna of any of the embodiments described above in addition to the illustrated configuration.

  In the fifth example, a plurality of antennas are attached, and even if a plurality of antennas are attached to the glass where only a narrow place remains, the fifth antenna 100 is good at two frequencies. Reception performance can be obtained.

<Characteristics of antenna>
Next, the characteristics of the antenna of this embodiment will be described.

  The following (FIGS. 6 to 7) is an explanation of antenna sensitivity when the arrangement or length of elements described below is changed, and the configuration of other elements is not changed. The antenna sensitivity is a value obtained by measuring the antenna sensitivity in all directions (360 degrees) in the horizontal plane and calculating the average.

FIG. 6 shows the antenna gain (sensitivity) in a low frequency band (315 MHz) when the length of the overlap portion 1A is changed in the antenna of the fifth embodiment. The lengths of the other elements are the same as described above. According to FIG. 6, the sensitivity was highest when the overlap portion 1A was 370 mm. At this time, the length of the overlap portion 1A is approximately αλ _1/2 when the wavelength λ ₁ = 315 MHz.

FIG. 7 shows an antenna gain (sensitivity) in a high frequency band (433.92 MHz) when the length of the non-overlap portion 1B of the first element 1 is changed in the antenna of the fifth embodiment. The lengths of the other elements are the same as described above. According to FIG. 7, the sensitivity was highest when the non-overlapping portion 1B was 235 mm. At this time, the length of the non-overlapping portion 1B, when the wavelength lambda ₂ = 433.92MHz, becomes substantially αλ _2/2.

  Although the present invention has been described in detail with reference to the accompanying drawings, the present invention is not limited to such specific configurations, and various modifications and equivalents within the spirit of the appended claims Includes configuration.

DESCRIPTION OF SYMBOLS 1 1st element 2 Feeding part 3 Bending part 10 1st antenna 50 2nd antenna 52 Horizontal filament 52F 2nd element 53 Vertical filament 54 2nd feeding part 60 3rd antenna 70 4th antenna 81 Rear glass 82 Body flange 90 Defogger 100 5th antenna

Claims (10)

A glass antenna disposed on a vehicle window glass,
A power supply connected to the receiver;
A first element extending from the power feeding unit,
The first element includes an overlap portion arranged at a predetermined interval along a second element that is not connected to the power feeding portion, and a non-overlap portion that is not along the second element. ,
The length of each of the overlap part and the non-overlap part is adjusted so that one of the overlap part and the non-overlap part is tuned in the first frequency band and the other is tuned in the second frequency band. A glass antenna characterized by that.   The glass antenna according to claim 1, wherein the second element is an element constituting an antenna different from the antenna provided with the first element. The glass antenna is a UHF band signal receiving antenna,
3. The glass antenna according to claim 2, wherein the antenna having the second element is a medium wave band AM broadcast receiving antenna.   The glass antenna according to any one of claims 1 to 3, wherein the first element is bent halfway.   5. The glass antenna according to claim 4, wherein a portion between the bent portion of the first element and the power feeding portion is configured by a plurality of filaments. The wavelength of the center frequency of the first frequency band is λ ₁ , and the wavelength of the center frequency of the second frequency band is λ ₂ ,
The wavelength reduction rate of the window glass as alpha, the length of the overlapping portion is substantially αλ _1/2, claim, wherein the length of the non-overlapping portion is substantially αλ _2/2 The glass antenna according to any one of 1 to 5.   The glass antenna according to claim 6, wherein the first frequency band is lower than the second frequency band.   The glass antenna according to claim 6 or 7, wherein a center frequency of the first frequency band is about 315 MHz, and a center frequency of the second frequency band is about 433.92 MHz.   The glass antenna according to any one of claims 1 to 8, wherein a distance between the first element and the second element in the overlap portion is 10 mm or less.   When the glass antenna is attached to an automobile, the body flange and the first element are capacitively coupled by disposing the first element at a position not less than 5 mm and not more than 10 mm from the edge of the body flange of the automobile. The glass antenna according to any one of claims 1 to 9, wherein

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