WO2010032285A1 - 車両用ガラスアンテナ - Google Patents
車両用ガラスアンテナ Download PDFInfo
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- WO2010032285A1 WO2010032285A1 PCT/JP2008/066667 JP2008066667W WO2010032285A1 WO 2010032285 A1 WO2010032285 A1 WO 2010032285A1 JP 2008066667 W JP2008066667 W JP 2008066667W WO 2010032285 A1 WO2010032285 A1 WO 2010032285A1
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- antenna
- broadcast wave
- wave receiving
- horizontal
- broadcast
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01Q—ANTENNAS, i.e. RADIO AERIALS
- H01Q1/00—Details of, or arrangements associated with, antennas
- H01Q1/12—Supports; Mounting means
- H01Q1/1271—Supports; Mounting means for mounting on windscreens
- H01Q1/1278—Supports; Mounting means for mounting on windscreens in association with heating wires or layers
Definitions
- the present invention relates to a glass antenna for receiving AM radio broadcast waves and FM radio broadcast waves provided on a rear window glass of a vehicle such as an automobile, and more particularly to a glass antenna suitable for receiving radio waves of FM radio broadcast waves.
- glass antennas for receiving AM radio broadcast waves and FM radio broadcast waves require a relatively large area in order to obtain a good reception gain, and are often provided on the rear window glass of an automobile.
- the rear window glass of an automobile is often provided with a heating line for anti-fogging in the central region for securing a rear view during running in rainy weather. For this reason, when providing a glass antenna in a rear window glass, it had to be provided in the upper margin part and lower margin part of the said heating wire for anti-fogging.
- both radio waves are received by a single antenna provided in the upper margin of the antifogging heating wire, and these AM radio band / FM radio band In most cases, the antenna has a grounded antenna pattern sharing one feeding point.
- an antenna amplifier is usually provided between the antenna feed point and the tuner, which is not sufficient for input to the tuner. In many cases, the electromotive force was amplified and input to the tuner.
- an impedance matching circuit is provided in order to minimize the reduction loss of the reception gain due to the feeder line between the antenna feeding point and the tuner so that the electromotive force sufficient to input to the tuner is maintained and input to the tuner. I was doing.
- an AM broadcast wave amplifier and an FM broadcast wave amplifier are separately provided for the amplifier, and after receiving power is amplified, the amplifier is input.
- the impedance matching circuit there is a case in which the AM broadcast wave impedance matching circuit and the FM broadcast wave impedance matching circuit suppress a reduction due to loss of reception sensitivity through a path for transmitting the radio wave received by the antenna to the tuner. Many.
- a glass antenna is provided in the upper margin of the rear window glass of the vehicle and is amplified by an amplifier.
- a microfilm disclosed in Japanese Utility Model Application No. 63-89982 Japanese Utility Model Application No. 2-13311
- Japanese Utility Model Application No. 63-89982 Japanese Utility Model Application No. 2-13311
- an amplifier for amplifying the reception sensitivity of the glass antenna the amplifier being soldered and brazed to a feeding terminal portion of the glass antenna.
- an amplifier mounting structure for an automotive glass antenna that is directly connected by means such as attaching a conductive adhesive, thereby reducing gain loss due to capacity loss in the feeder line portion between the glass antenna and the amplifier.
- JP-A-11-205023 discloses a first coil, a second coil, a first antenna conductor provided on a window glass plate of a vehicle, and a second antenna conductor provided on the window glass plate.
- the first resonance including the impedance of the first antenna conductor and the inductance of the first coil as a resonance element is generated, and the impedance of the second antenna conductor and the inductance of the second coil are resonated.
- a second resonance included as an element, the second antenna conductor has a conductor length and a conductor shape for the first reception frequency band, and the first antenna conductor is from the first reception frequency band.
- Patent Document 2 Microfilm of Japanese Utility Model No. 63-89982 (Japanese Utility Model Application No. 2-13311) JP 11-205023 A
- Patent Document 1 an antenna for receiving an AM broadcast wave and an FM broadcast wave is provided in a margin of a rear window glass of an automobile, and the receiving sensitivity of the glass antenna is provided at a feeding terminal of the antenna.
- a structure in which an amplifier for amplifying the signal is attached is described.
- the amplifier is a different circuit in the reception frequency band, that is, the AM broadcast wave band and the FM broadcast wave band, and the AM broadcast wave amplifier and the FM broadcast wave amplifier must be separated from each other, and between the antenna feeding point and the amplifier.
- the antenna amplifier is designed to be demultiplexed into both AM and FM broadcast frequency bands by the demultiplexing circuit, and then amplified by the AM and FM broadcast wave amplifiers for synthesis. When the size is increased and it is attached at or near the feeding point, it looks bad. Further, even if it is provided inside the interior material of the side pillar portion of the rear window, it not only becomes an obstacle, but its manufacturing cost is not low.
- Patent Document 2 two broadcast wave band antennas, a first antenna for a high band and a second antenna for a low band, are provided on an upper part of a defogger of a rear window glass of an automobile.
- the antenna is capacitively coupled, and the sensitivity of the two frequency bands is improved by using different resonances for each antenna, and both the AM radio band and FM radio band are tuned separately. Therefore, the tuning operation can be simplified.
- the glass antenna of the present invention is mass-produced, there is a problem that satisfactory reception characteristics cannot always be obtained due to variations in elements of each circuit.
- the present invention aims to solve the above-mentioned problem, that is, in an antenna for receiving an AM broadcast wave and an FM broadcast wave provided in a blank portion of an antifogging heating strip on a rear window glass of an automobile, particularly for an FM radio broadcast wave.
- the present invention provides an antenna that does not require an amplifier or a matching circuit for FM radio broadcast waves with a high reception gain.
- the present invention is a glass antenna for a vehicle provided in an upper margin of a heating wire for anti-fogging of a rear window glass of a vehicle,
- a plurality of horizontal filaments provided at intervals and at least two vertical filaments perpendicular to the horizontal filaments are provided apart from each other, and between the vertical filaments and on the uppermost horizontal filament or the uppermost segment.
- the first glass antenna has an FM broadcast wave receiving antenna in which a second horizontal line extending in a horizontal direction from the second feeding point is close and capacitively coupled to the horizontal line of the AM broadcast wave receiving antenna. Further, an L-shape or a U-shape having at least a second vertical line extending in a substantially vertical direction or in an arc shape along the outside of the plurality of horizontal lines of the AM broadcast wave receiving antenna from the tip thereof. It may be a glass antenna (second glass antenna) for a vehicle characterized by being an element of the above.
- the first or second glass antenna has one or two folded horizontal filaments at the tip of the FM broadcast wave receiving antenna, and is close and capacitively coupled to the tip of the AM broadcast wave receiving horizontal filament. It may be a glass antenna (third glass antenna) for a vehicle.
- any one of the first to third glass antennas sandwiches the first feeding point, and two FM broadcast wave receiving antennas are separately provided from each of the two second feeding points provided on both sides of the first feeding point.
- a vehicle glass antenna (fourth glass antenna), characterized in that each of the two systems is extended to the outermost periphery of the AM broadcast wave receiving antenna in the clockwise and counterclockwise directions for diversity reception. ).
- any one of the first to fourth glass antennas is characterized in that the horizontal wire of the AM broadcast wave receiving antenna is capacitively coupled in proximity to the horizontal wire of the antifogging heating wire.
- the vehicle glass antenna (fifth glass antenna) may be used.
- any one of the first to fifth glass antennas has an auxiliary vertical wire extending upward from an upper end portion of the bus bar of the antifogging heating wire, and at least a second vertical of the FM broadcast wave receiving antenna. It may be a glass antenna (sixth glass antenna) for a vehicle that is close to the outside of the filament and capacitively coupled.
- any one of the first to sixth glass antennas is connected to a tuner via an AM radio broadcast wave amplifier from a first feeding point of the AM broadcast wave reception antenna to receive FM broadcast waves. It may be a glass antenna for a vehicle (seventh glass antenna) that is directly connected to the tuner from the second feeding point of the antenna without using an amplifier or an impedance matching circuit.
- any one of the first to seventh glass antennas has a frequency of 76 to 90 MHz as a first horizontal line length from the second feeding point to the tip of the FM broadcast wave receiving antenna.
- it is 200 to 500 mm
- it is used as an FM broadcast wave receiving antenna for North America, Europe and Australia with a frequency of 88 to 108 MHz, it is set to 150 to 400 mm.
- each horizontal line of the portion where the second horizontal line or folded horizontal line of the antenna of the antenna and the horizontal line of the antenna for receiving the AM broadcast wave are close to each other and capacitively coupled, and the line of the line
- the frequency is 200 to 400 mm, 5 to 30 mm.
- an antenna for receiving FM broadcast waves for North America, Europe, and Australia in the 88 to 108 MHz band is used, it is a glass antenna (8th glass antenna) for vehicles characterized by being 150 to 400 mm and 2 to 30 mm. Also good.
- any one of the first to eighth glass antennas is provided for a vehicle, wherein at least two vertical filaments provided so as to cross a plurality of horizontal filaments of the antifogging heating filament are provided. It may be a glass antenna (9th glass antenna).
- the front view which shows the glass antenna by Example 1 of this invention provided in the rear window glass for vehicles.
- the front view which shows the glass antenna by Example 2 of this invention provided in the rear window glass for vehicles.
- the front view which shows the glass antenna by Example 3 of this invention provided in the rear window glass for vehicles.
- the front view which shows the glass antenna by Example 4 of this invention provided in the rear window glass for vehicles.
- the second horizontal line or part of the folded horizontal line of the FM broadcast wave receiving antenna provided in the upper margin of the antifogging heating wire line (defogger) of the rear window glass of the vehicle is used for receiving the AM broadcast wave.
- the reception sensitivity of the FM broadcast wave receiving antenna is greatly improved, and FM broadcast wave reception is achieved. It is no longer necessary to connect an amplifier or impedance matching circuit between the second feeding point of the antenna and the tuner.
- the antifogging heating filament (defogger) and the lowermost horizontal filament of the AM broadcast wave receiving antenna are brought close to each other and capacitively coupled, the antifogging heating filament ( The AM broadcast wave received by the defogger) can be picked up, and the reception characteristics can be further improved as compared with the case where the AM broadcast wave is received only by the antenna 4 for receiving the AM broadcast wave.
- the folded horizontal filaments at the tips of the main antenna 5 and the sub-antenna 5 'for FM broadcast wave reception are close to the uppermost horizontal filament of the antifogging heating filament (defogger) and capacitively coupled.
- the FM broadcast wave received by the cloudy heating wire (defogger) can be picked up, and reception characteristics can be improved as compared with the case where only the main antenna 5 and the sub-antenna 5 ′ for FM broadcast wave reception are received. Can do.
- the AM broadcast wave band amplifier and the FM broadcast wave band amplifier as in the prior art are placed in one storage case and arranged in the vicinity of the pillar of the rear window glass. Since the FM broadcast wave amplifier, which occupied the majority, is no longer needed, the storage case is not only significantly reduced in size to a fraction of the size, but also only for AM broadcast wave amplifiers. Therefore, the manufacturing cost can be greatly reduced.
- the two antennas, the AM broadcast wave receiving antenna 4 and the FM broadcast wave receiving antenna 5, are completely separated from the upper margin of the antifogging heating wire 2 of the rear window glass 1 for the vehicle.
- the antifogging heating wire 2 (commonly referred to as defogger) has a plurality of substantially horizontal heating wires 2a arranged in parallel in the central region of the rear window glass 1 for a vehicle, and both ends thereof are electrically conductive bus bars. 3, 3 'are connected, and the fogging is removed by evaporating moisture on the surface of the window glass by energization heating.
- the AM broadcast wave receiving antenna 4 includes a plurality of horizontal wires provided at intervals, and a vertical wire provided perpendicularly to the horizontal wires and provided at least two apart.
- At least two vertical lines of the AM broadcast wave receiving antenna 4 are extended from the horizontal line at the top position so that at least one vertical line is orthogonal to all the horizontal lines, and the other vertical lines.
- the wire is connected perpendicularly to all or part of the horizontal wire.
- the vertical lines 4b, 4b that intersect and connect to the plurality of horizontal lines 4a, 4a,... are in the vicinity of positions that divide the plurality of horizontal lines 4a, 4a,.
- the horizontal lines 4a, 4a,... are not the same length, but are shifted to the left or right, or the length of one of the left and right sides may be slightly shorter.
- the vicinity of the position that is substantially divided into three equals the vicinity of the position where the maximum width of the horizontal filaments 4a and 4a is substantially divided into three, but is not limited to this, and the vertical filaments 4b and 4b are further separated in the left-right direction. Thus, it may be a position moved to approximately the positions of the left and right sides of the substantially equally divided position.
- the AM radio broadcast on the defogger This is desirable because radio waves for waves can be picked up.
- the FM broadcast wave receiving antenna 5 is connected to the outermost peripheral portion of the AM broadcast wave receiving antenna 4 from a second feeding point 8 provided above the horizontal line 4a at the top of the AM broadcast wave antenna 4.
- the antenna 4 for receiving the AM broadcast wave is enclosed in a clockwise or counterclockwise direction along a part of the antenna 4 and is close to and at least part of the horizontal line 4a of the antenna 4 for receiving the AM broadcast wave. It is intended to be combined.
- 4a close to and capacitively coupled to 4a, and in a substantially vertical direction along the outer contour of the plurality of horizontal lines 4a, 4a,... Of the AM broadcast wave receiving antenna 4 from the tip of the second horizontal line 5a.
- it may have an L shape having at least a second vertical line 5b extending in an arc shape, and further, a horizontal line at the bottom of the antenna 4 for receiving AM broadcast waves from the tip of the second vertical line 5b. It is good also as an element of the shape folded in U shape along the lower part of 4a, or in the middle of horizontal filament 4a, 4a, ....
- the FM broadcast wave receiving antenna 5 has one or two folded horizontal filaments 5c, and a part of the folded one or two folded horizontal filaments 5c of the AM broadcast wave receiving antenna 4. Capacitive coupling may be performed in the vicinity of a part of the tip of the horizontal filaments 4a, 4a,.
- the auxiliary vertical wires 2c and 2c ′ extending upward from the upper ends of the bus bars 3 and 3 ′ of the antifogging heating wire 2 are at least the second vertical wires 5b of the FM broadcast wave receiving antenna 5. It is desirable to be close along the outside and capacitively coupled. This is because the radio waves for FM radio broadcast waves placed on the antifogging heating wire 2 can be picked up via the auxiliary vertical wires 2c, 2c '.
- the FM broadcast wave receiving antennas 5, 5 ′ are sandwiched between the two second feed points 8, 8 ′ provided on both sides of the first feed point 7 of the AM broadcast wave receiving antenna 4. It is desirable that two systems are provided separately, and that each of the two systems is extended to the outermost peripheral portion of the AM broadcast wave receiving antenna 4 in the clockwise and counterclockwise directions for diversity reception.
- the AM broadcasting wave receiving antenna 4 is connected to the tuner 14 via the AM radio broadcasting wave amplifier 10 from the first feeding point 7, and the FM broadcasting wave receiving antennas 5 and 5 ′ are fed second.
- the points 8 and 8 ' can be directly connected to the tuner 14 without using an amplifier or an impedance matching circuit.
- the antennas 5 and 5 'for receiving FM broadcast waves may be connected to the tuner 14 via an amplifier or an impedance matching circuit from the second feeding points 8 and 8'.
- An FM broadcast wave receiving antenna for use in Japan having a frequency of 76 to 90 MHz as a line length from the second feeding point 8 and 8 'to the tip of the FM broadcast wave receiving antenna 5 and 5' extending from the second feeding point 8 and 8 '.
- it is 200 to 500 mm
- it is an antenna for receiving FM broadcast waves for North America, Europe and Australia having a frequency of 88 to 108 MHz, it is preferably 150 to 400 mm.
- Second horizontal line 5a, 5a 'or folded horizontal line 5c, 5c' of FM broadcast wave receiving antenna 5, 5 and the horizontal line of AM broadcast wave receiving antenna are close to each other and capacitively coupled.
- the antenna is used as an FM broadcast wave receiving antenna having a frequency of 76 to 90 MHz in Japan
- the length of the wire and the interval between the portions are 200 to 500 mm, 2 to 30 mm, preferably 5 to 15 mm. It is good to do.
- the antenna for receiving FM broadcast waves for North America, Europe, and Australia having a frequency of 88 to 108 MHz is used, the antenna is set to 150 to 400 mm and 2 to 30 mm.
- at least two vertical filaments were provided so as to be orthogonal to the plurality of horizontal filaments 2a of the antifogging heating filament.
- the FM broadcast wave receiving antennas 5 and 5 ′ have sufficient reception characteristics even if only one of them is received, but with diversity reception using one as a main antenna and the other as a sub-antenna, and input to the tuner 14, This is preferable because directivity is improved as compared with the case where only one of the antennas 5 and 5 'for receiving FM broadcast waves is received alone and input to the tuner 14.
- the antifogging heating wire 2 is provided in the central region of the rear window glass 1, and a plurality of substantially horizontal heating wires 2a are arranged substantially horizontally, and both ends thereof are electrically conductive bus bars 3, 3 Connected with 'and heated by energization with a DC power source (not shown).
- the vertical filament 2b connecting the points obtained by dividing each of the plurality of substantially horizontal filaments 2a of the antifogging heating filament 2 into approximately three equal parts is a neutral filament that is not energized, and is an antifogging heating filament.
- the antifogging heating wire 2 also functions as an antenna, and it is effective to improve the reception gain of the AM / FM broadcast wave using the radio wave received by the antifogging heating wire 2. However, it is not always necessary.
- the auxiliary vertical filaments 2c and 2c ′ extending upward from the upper ends of the bus bars 3 and 3 ′ of the antifogging heating filament 2 are not necessarily required. Absent.
- auxiliary vertical filaments 2c and 2c ′ are close to each other along the outside of the second vertical filament 5b of the FM broadcast wave receiving antenna 5 and are capacitively coupled. Can be picked up via the auxiliary vertical wires 2c, 2c ′, and thus effectively acts to widen the frequency characteristics and improve the receiving sensitivity.
- the FM broadcast wave receiving antenna of the present invention can provide good reception sensitivity without connecting an amplifier or an impedance matching circuit between the second feeding point of the FM broadcast wave receiving antenna and the tuner. Needless to say, further improvement in reception sensitivity can be obtained by connecting an amplifier or an impedance matching circuit.
- the AM broadcast wave receiving antenna 4 and the FM broadcast wave receiving antenna 5 are provided as separate and independent antennas, and therefore can be tuned to a line length suitable for each reception frequency. Tuning work is also easy.
- the radio waves for AM broadcast waves are amplified by the AM broadcast wave band amplifier 10 and input to the tuner 14 as in the prior art.
- the feed points 8, 8 'of the FM broadcast wave receiving antennas 5, 5' Capacitors 13 and 13 ′ for blocking the frequency band of AM radio broadcast waves are connected in series near the output side.
- radio waves for FM broadcast waves are transmitted to the second end of the antenna 4 for receiving FM broadcast waves at a part of the tip of any of the plurality of horizontal wires 4a, 4a,.
- the FM broadcast wave antenna picked up by the FM broadcast wave antenna 5 is received by the AM broadcast wave antenna 4 by bringing the horizontal filaments 5a, 5a ′ or the folded horizontal stripes 5c, 5c ′ into close proximity and capacitive coupling.
- the reception sensitivity of the FM broadcast wave receiving antenna 5 can be improved, and an FM broadcast wave band amplifier or impedance matching is provided between the second feeding point 8 of the FM broadcast wave receiving antenna 5 and the tuner 14. There is no need to connect a circuit.
- a part of the second horizontal line 5a, 5a ′ or the folded horizontal line 5c, 5c ′ of the antenna 5 for receiving FM broadcast waves is close to a part of the horizontal line 4a of the antenna 4 for receiving AM broadcast waves.
- a folded horizontal filament 5c, 5c ′ at the tip of the FM broadcast wave receiving antenna 5 one of the tip of the folded horizontal filament 5c, 5c ′. If the part is brought close to a part of the tip of the horizontal line 4a of the antenna 4 for receiving an AM broadcast wave and capacitively coupled, more reliable capacitive coupling is achieved and stable performance is obtained.
- auxiliary vertical wires 2c and 2c ′ extending upward from the upper ends of the bus bars 3 and 3 ′ of the heating conductive wire 2 are connected to the FM broadcast wave receiving antenna 5. At least along the outer side of the vertical line 5b and capacitively coupled, the radio wave for FM radio broadcast wave placed on the antifogging heating line 2 is transmitted via the auxiliary vertical lines 2c, 2c ′. This is because the reception gain can be improved.
- two antennas for receiving FM broadcast waves are the main antenna 5 and the other antenna are sub-antennas 5 ', but either antenna may be the main antenna.
- the antenna sensitivity of substantially the same level as the main antenna 5 for receiving FM broadcast waves can be obtained.
- Diversity reception of the main antenna 5 and the sub-antenna 5 ′ makes it possible to complement each other with a low reception characteristic and a low directivity characteristic.
- an AM broadcast wave receiving antenna 4 and a frequency band of 88 to 108 MHz for North America, Europe, and Australia are provided in the upper margin of the antifogging heating filament 2 of the rear window glass for automobiles.
- the AM broadcast wave receiving antenna 4 includes four horizontal lines 4a, 4a,... Provided at intervals, and two vertical lines 4b, 4b provided so as to be orthogonal to the horizontal lines.
- the two vertical filaments 4b and 4b are provided at positions that divide the horizontal filament 4a into approximately three equal parts, and the vertical filament 4b on one side includes four horizontal filaments 4a from the top to the bottom.
- the other vertical line 4b is orthogonally crossed from the uppermost horizontal line to the third horizontal line 4a, and is provided slightly above the intersection of the other vertical line and the uppermost horizontal line. 1 was connected to the feeding point 7 through a leader line.
- the length of the lowest horizontal filament 4a is shorter than that of the first to third horizontal filaments 4a. Capacitive coupling was performed in proximity to the uppermost heating wire 2a.
- the main FM broadcast wave receiving antenna 5 is provided with an AM broadcast wave receiving antenna from a second feeding point 8 provided in the vicinity of the upper position of the vertical line of the AM broadcast wave receiving antenna 4.
- 4 is an antenna wire extending in a counterclockwise direction along the uppermost horizontal wire 4 so as to be close to each other and capacitively coupled.
- the sub FM broadcast wave receiving antenna 5 ′ has a horizontal line at the top of the AM broadcast wave receiving antenna 4 from a second feeding point 8 ′ provided near the right side of the first feeding point 7.
- the second horizontal line 5a ' is extended clockwise along the line 4a so as to be close to each other and capacitively coupled, and further, substantially perpendicular so as to surround the right end of each horizontal line of the AM broadcast wave receiving antenna 4.
- the second vertical filament 5b ′ is extended in the direction, and a folded filament 5c ′ folded from the tip thereof is provided, and the folded filament 5c ′ is brought close to the top end of the lowermost horizontal filament 4a and capacitively coupled. .
- the AM broadcast wave receiving antenna 4 is connected to the tuner 14 via the AM radio broadcast wave band amplifier 10 from the first feeding point 7, and the second FM broadcast wave receiving antennas 5, 5 ′ are connected.
- the feed points 8 and 8 ' were directly connected to the tuner 14 without passing through FM broadcast wave amplifiers or impedance matching circuits.
- the glass plate 1 has a substantially trapezoidal shape, and the approximate dimensions are 1,100 mm for the upper side, 1,300 mm for the lower side, and 500 mm for the height.
- the inner diameter of the flange of the window frame is 1,000 mm for the upper side,
- the height is 1,100 mm and the height is 400 mm.
- the lengths of the lines of the AM broadcast wave receiving antenna 4 of the present invention are as follows.
- Each length of vertical filament 4b, 4b 70mm, 50mm
- Each interval between the vertical filaments 4b, 4b 300mm
- the length of each filament of FM broadcast wave receiving antennas 5 and 5 'of the present invention is as follows.
- the distance between the second horizontal line 5a, 5a 'of the FM broadcast wave receiving antenna 5, 5' and the uppermost horizontal line 4a of the AM broadcast wave receiving antenna 4, and the FM broadcast wave receiving antenna 5 ' The distance between the folded horizontal line 5c ′ and the horizontal line 4a at the bottom of the AM broadcast wave receiving antenna 4 was 5 mm.
- the position of the first feeding point 7 is 150 mm to the right of the center line of the glass plate, and this position is also the position of the vertical line 4 b of the AM broadcast wave receiving antenna 4 and the vertical line 2 b ′ of the defogger 2. is there.
- the second horizontal line 5a of the FM broadcast wave receiving main antenna 5 is close to the left end of the uppermost horizontal line 4a of the AM broadcast wave receiving antenna 4 by a length of 450 mm, and is used for FM broadcast wave reception.
- the horizontal line 5a ′ of the sub-antenna 5 ′ and the right end of the horizontal line 4a at the top of the AM broadcast wave receiving antenna 4 are brought closer to each other by a length of 210 mm, and the folded horizontal line 5c ′ and the AM broadcast wave receiving antenna 4 are It was made to approach by the length of 100 mm from the right end of the lowest horizontal filament 4a.
- the distance between the uppermost horizontal line 4a of the AM broadcast wave receiving antenna 4 and the inner side of the upper side of the flange (not shown) is 30 mm, and the distance between the lowermost horizontal line 4a and the uppermost heating line 2a. About 10 mm away.
- AM broadcast wave receiving antenna 4, FM broadcast wave receiving main antenna 5, FM broadcast wave receiving sub-antenna 5 ′, and heating conductive wire 2, each feeding point, and bus bar are made of conductive paste such as silver paste. It is formed by printing on a glass plate surface and firing.
- the window glass plate thus obtained is attached to the rear window of the automobile, and further connected to the AM broadcast wave band amplifier 10 through the feeder line from the first feeding point 7 of the AM broadcast wave receiving antenna 4.
- the FM broadcast wave receiving antennas 5 and 5 ′ are connected to the output terminal of the AM broadcast wave band amplifier 10 from the second feeding points 8 and 8 ′ via the AM band cutoff capacitors 13 and 13 ′, respectively. Then, the AM broadcast radio wave radio wave and the FM broadcast radio wave radio wave were combined and connected to the tuner 14 via a feeder line.
- main antenna 5 and the sub-antenna 5 ′ for receiving FM broadcast waves are configured to receive diversity in order to improve directivity characteristics, and any of them may be a main antenna.
- the average reception gain of the vertical polarization of the FM broadcast wave band for North America, Europe and Australia as shown in FIG. are -8.6 dB and -9.5 dB (dipole ratio), respectively.
- the average reception gain of vertically polarized waves in the FM broadcast wave band of 88 MHz to 108 MHz is -8.3 dB (dipole ratio), and the impedance matching circuit is installed even though no FM broadcast wave amplifier or impedance matching circuit is provided.
- the average reception gain ( ⁇ 17 dB) in the case of being provided it is improved by 10 dB, and a very excellent reception gain is obtained. It was found to be.
- AM broadcast waves are amplified by an AM broadcast wave band amplifier as before, so there is no problem in practical use.
- the AM broadcasting wave receiving antenna horizontal line and the FM broadcasting wave receiving antenna horizontal line are close and capacitively coupled to each other, thereby receiving both the AM broadcasting wave and the FM broadcasting wave. Without degrading the characteristics, an FM broadcast wave receiving amplifier and an impedance matching circuit are not required, and only an AM broadcast wave receiving amplifier and an AM band cut-off capacitor need be provided. *
- the amplifier is only for AM, compared to the case where two amplifiers for AM and FM are required, the total volume occupied by the amplifier is reduced to a fraction or less, and the production cost is also reduced. You can save a lot.
- Example 2 shown in FIG. 2 includes five horizontal filaments and two vertical filaments orthogonal to the upper margin of the anti-fogging heating filament of the rear window glass for automobiles as in Example 1.
- An AM broadcast wave receiving antenna, a U-shaped FM broadcast wave receiving main antenna and a sub-antenna are provided close to each other so as to be sandwiched from both sides of the AM broadcast wave receiving antenna, and the antifogging heating wire
- the auxiliary vertical wire is extended along the outside of the FM broadcast wave receiving main antenna and the sub antennas above the upper ends of the two bus bars.
- the AM broadcast wave receiving antenna has five horizontal lines
- the FM broadcast wave receiving main antenna 5 is connected to the outermost periphery of the AM broadcast wave receiving antenna from the second feeding terminal 8.
- the auxiliary vertical wire 2c, 2c ′ extending upward from the upper end of the bus bar is provided with the FM broadcast wave receiving main antenna 5 in a counterclockwise U-shaped line along the portion.
- the second vertical filaments 5b and 5b ′ of the sub-antenna 5 ′ are capacitively coupled.
- the AM broadcast wave receiving antenna 4 is connected to the tuner 14 via the AM radio broadcast wave band amplifier 10 from the first feeding point 7 to receive the FM broadcast wave receiving antenna 5.
- the second feed points 8 and 8 ′ of 5 ′ were directly connected to the tuner 14 without passing through FM broadcast wave amplifiers or impedance matching circuits.
- the lengths of the lines of the AM broadcast wave receiving antenna 4 of the present invention are as follows.
- Each length of the vertical filaments 4b, 4b 70mm, 70mm
- Each interval between the vertical strips 4b and 4b 460 mm
- the length of each filament of FM broadcast wave receiving antennas 5 and 5 'of the present invention is as follows.
- Each interval between the second horizontal wires 5a and 5a 'of the FM broadcast wave receiving antennas 5 and 5' and the uppermost horizontal wire 4a of the AM broadcast wave receiving antenna 4 5 mm
- the distance between the folded horizontal filament 5c of the FM broadcast wave receiving antenna 5 and the uppermost heating filament 2a of the antifogging heating filament 2 5 mm,
- the interval between the folded horizontal filament 5c ′ of the FM broadcast wave receiving antenna 5 and the uppermost heating filament 2a of the antifogging heating filament 2 is 15 mm.
- the position of the first feeding point 7 is 155 mm to the right of the center line of the glass plate G, and the position of the second feeding point 8 for the FM broadcast wave receiving main antenna 5 is from the center line of the glass plate.
- the position of the second feeding point 8 ′ for the FM broadcast wave receiving sub-antenna 5 ′ is provided 215 mm to the left of the center line of the glass plate.
- the second horizontal line 5a of the FM broadcast wave receiving main antenna 5 is close to the left end of the top horizontal line 4a of the AM broadcast wave receiving antenna 4 by a length of 265 mm, and is used for FM broadcast wave reception.
- the second horizontal filament 5a 'of the sub-antenna 5' and the right end of the uppermost horizontal filament 4a of the AM broadcast wave receiving antenna 4 are brought closer to each other by a length of 200 mm, and the folded horizontal filament 5c and the AM broadcast wave receiving antenna are placed.
- 4 is brought closer to the left end of the horizontal line 4a at the lowermost part by 80mm, and the folded horizontal line 5c 'is closer to the right end of the lowermost horizontal line 4a of the AM broadcast wave receiving antenna 4 by a length of 75mm. I tried to make it.
- the distance between the uppermost horizontal line 4a of the AM broadcast wave receiving antenna 4 and the inner side of the upper side of the flange (not shown) is 30 mm, and the distance between the lowermost horizontal line 4a and the uppermost heating line 2a. About 10 mm away.
- AM broadcast wave receiving antenna 4, FM broadcast wave receiving main antenna 5, FM broadcast wave receiving sub-antenna 5 ′, and heating conductive wire 2, each feeding point, and bus bar are made of conductive paste such as silver paste. It is formed by printing on a glass plate surface and firing.
- the window glass plate thus obtained is mounted on the rear window of the automobile, and, similarly to the first embodiment, for the AM broadcast wave band by the feeder line from the first feeding point of the AM broadcast wave receiving antenna 4.
- the AM broadcast wave band amplifier 10 is supplied from the second feeding points 8 and 8' via the AM band cutoff capacitors 13 and 13 ', respectively.
- the AM broadcast radio band radio wave and the FM broadcast radio band radio wave were combined and connected to the tuner 14 via a feeder line.
- the average reception gain of horizontally polarized waves in the domestic FM broadcast wave band of 76 MHz to 90 MHz is ⁇ 15.3 dB and ⁇ 14.6 dB (dipole ratio).
- the FM main antenna 5 and the FM sub-antenna 5 ′ the above-mentioned 88 MHz to 108 MHz
- the average reception gain of horizontally polarized waves in the FM broadcast wave band is -11.4 dB (dipole ratio), and there is no FM broadcast wave amplifier or impedance matching circuit, but an impedance matching circuit is provided. It was found that the reception gain was significantly improved compared to the average reception gain ( ⁇ 17 dB).
- AM broadcast waves are amplified by an AM broadcast wave band amplifier as before, so there is no problem in practical use.
- the amplifier since the amplifier is only for AM broadcast wave reception, the total volume occupied by the amplifier is less than a fraction of that required when two amplifiers for AM broadcast wave reception and FM broadcast wave reception are required. It has become more compact and the production cost can be greatly reduced.
- the third embodiment shown in FIG. 3 is a modification of the second embodiment, and the tip portion of the substantially U-shaped pattern of the sub-antenna 5 ′ used for receiving FM broadcast waves for domestic use in the frequency band of 76 to 90 MHz.
- the folded horizontal line 5c ′ is made into two lines, and a part of the right end of the fourth horizontal line from the top of the AM broadcast wave receiving antenna 4 is brought close to and sandwiched between the two folded horizontal lines 5c ′ and capacitively coupled.
- the AM broadcast wave receiving antenna has five horizontal strips, but the length of each strip is substantially the same as in the second embodiment.
- the present embodiment is a modified pattern of the second embodiment.
- the horizontally polarized wave in the domestic FM broadcast wave band of 76 MHz to 90 MHz is obtained.
- the average reception gain of horizontal polarization of the FM broadcast wave band of 88 MHz to 108 MHz is ⁇ 11.4 dB (dipole ratio), and no FM broadcast wave amplifier or impedance matching circuit is provided.
- the reception gain is greatly improved. Rukoto was found.
- AM broadcast waves are amplified by an AM broadcast wave band amplifier as before, so there is no problem in practical use.
- an AM broadcast wave receiving amplifier and an impedance matching circuit are not required without deteriorating the reception characteristics of both the AM broadcast wave and the FM broadcast wave. And was able to.
- Such an AM broadcast wave receiving antenna 4 is connected to an AM broadcast wave band amplifier through a feeder line from the first feeding point 7 of the AM broadcast wave receiving antenna 4, and the FM broadcast wave receiving main antenna 5 and sub-antenna 5 ′ are
- the AM broadcast wave band radio wave and the FM broadcast wave band radio wave are connected to the output terminal of the AM broadcast wave band amplifier 10 through the AM band cutoff capacitors 13 and 13 'from the feed points 8, 8' Were connected to the tuner 14 by a feeder line.
- the main antenna 5 and the sub-antenna 5 ′ for receiving FM broadcast waves are connected to the tuner 14 from the second feeding points 8 and 8 ′ via the AM band cut-off capacitor 13 ′, and two FM broadcast waves. Since the reception antennas 5 and 5 'are made to receive diversity, higher reception characteristics and directivity characteristics can be obtained, and FM broadcast waves can be received without degrading reception characteristics of both AM broadcast waves and FM broadcast waves. Broadcast amplifiers and impedance matching circuits can be eliminated.
- the fourth embodiment shown in FIG. 4 is a modification of the first embodiment, and is a substantially U-shaped sub-antenna 5 'used for receiving FM broadcast waves for North America, Europe and Australia having a frequency band of 88 to 108 MHz.
- the folded horizontal line 5c ′ at the tip of the pattern is made into two lines, a part of the right end of the lowermost horizontal line of the AM broadcast wave receiving antenna 4 and the two folded horizontal lines 5c ′, 5c ′.
- the lower side is close and capacitively coupled, and the length of each filament is substantially the same as in the first embodiment.
- the present embodiment is a modified pattern of the first embodiment.
- FM broadcast wave bands for North America, Europe and Australia of 88 MHz to 108 MHz are shown.
- the average reception gain of vertically polarized waves becomes ⁇ 9 dB and ⁇ 9.5 dB (dipole ratio), respectively, and diversity reception is performed by the FM main antenna 5 and the FM sub-antenna 5 ′.
- the average reception gain of vertically polarized waves in the FM broadcast wave band of 88 MHz to 108 MHz is ⁇ 8.5 dB (dipole ratio), even though no FM broadcast wave amplifier or impedance matching circuit is provided.
- the average reception gain (-17 dB) when an impedance matching circuit is provided it is greatly received by nearly 10 dB. It was found that the improvement of the gain can be obtained.
- AM broadcast waves are amplified by an AM broadcast wave band amplifier as before, so there is no problem in practical use.
- Such an AM broadcast wave receiving antenna 4 is connected to the AM broadcast wave band amplifier 10 from the first feeding point 7 of the AM broadcast wave receiving antenna 4 through a feeder line, and the FM broadcast wave receiving main antenna 5 and sub-antenna 5 ′ are as follows: Connected to the output terminal of the AM broadcast wave band amplifier 10 from the second feed points 8 and 8 'via the AM band cut-off capacitors 13 and 13', the AM broadcast wave band radio wave and the FM broadcast wave band use The radio wave was synthesized and connected to the tuner 14 by a feeder line.
- the main antenna 5 and the sub-antenna 5 ′ for receiving FM broadcast waves are connected to the tuner 14 from the second feeding points 8 and 8 ′ via the AM band cut-off capacitor 13 ′, and two FM broadcast waves. Since the reception antennas 5 and 5 'are made to receive diversity, higher reception characteristics and directivity characteristics can be obtained, and FM broadcast waves can be received without degrading reception characteristics of both AM broadcast waves and FM broadcast waves. Broadcast amplifiers and impedance matching circuits can be eliminated.
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Abstract
Description
間隔を隔てて設けた複数本の水平線条と、該水平線条と直交する垂直線条を少なくとも2本離隔して設け、該垂直線条間で、かつ最上部の水平線条上、あるいは該最上部の水平線条の該部より引出線を介して設けた位置を第1の給電点とするAM放送波受信用のアンテナと、
前記AM放送波用アンテナの最上部の水平線条より上部に設けた第2の給電点より前記AM放送波受信用アンテナの最外周部の一部に沿って時計回り又は反時計回りの方向に延ばして前記AM放送波用アンテナを囲み、前記AM放送波受信用のアンテナの水平線条の少なくとも一部に近接かつ容量結合するようにしたFM放送波受信用アンテナとを含む、車両用のガラスアンテナ(第1ガラスアンテナ)を提供する。
図1に示すように、自動車用の後部窓ガラスの防曇用加熱線条2の上部余白部に、AM放送波受信用のアンテナ4と、周波数が88~108MHz帯の北米・欧州・豪州向けのメインとサブのFM放送波受信用アンテナ5、5’を設けた。
水平線条4a間の間隔=20mm
垂直線条4b、4bの各長さ=70mm、50mm
垂直線条4b、4b間の各間隔=300mm
また、本発明のFM放送波受信用アンテナ5、5’の各線条の長さは以下の通りである。
第2の垂直線条5b’の長さ=70mm
折返し水平線条5c’の長さ=150mm
FM放送波受信用アンテナ5、5’の第2の水平線条5a、5a’と、AM放送波受信用アンテナ4の最上部の水平線条4a間の間隔、及びFM放送波受信用アンテナ5’の折返し水平線条5c’と、AM放送波受信用アンテナ4の最下部の水平線条4a間の間隔は、それぞれ5mmとした。
図2に示す実施例2は、実施例1と同様に自動車用の後部窓ガラスの防曇用加熱線条の上部余白部に5本の水平線条およびこれと直交する2本の垂直線条からなるAM放送波受信用アンテナと、該AM放送波受信用アンテナの両側より挟み込むようにコ字状のFM放送波受信用メインアンテナとサブアンテナを近接して設け、さらに、前記防曇用加熱線条の2つのバスバーの上端部より上方に補助垂直線条を前記FM放送波受信用メインアンテナ、及びサブアンテナの垂直線条の外側に沿って延ばしたものである。
水平線条4a間の間隔=20mm、一番下は10mm
垂直線条4b、4bの各長さ=70mm、70mm
垂直線条4b、4b間の各間隔=460mm
また、本発明のFM放送波受信用アンテナ5、5’の各線条の長さは以下の通りである。
第2の垂直線条5b、5b’の長さ=40mm、30mm
第2の水平線条5c、5c’の長さ=80mm、75mm
FM放送波受信用アンテナ5、5’の第2の水平線条5a、5a’と、AM放送波受信用アンテナ4の最上部の水平線条4a間の各間隔=5mm
FM放送波受信用アンテナ5の折返し水平線条5cと、防曇用加熱線条2の最上部の加熱線条2a間の間隔=5mm、
FM放送波受信用アンテナ5の折返し水平線条5c’と、防曇用加熱線条2の最上部の加熱線条2a間の間隔は=15mm、
図3に示す実施例3は、実施例2の変形例であって、周波数が76~90MHz帯の国内向けFM放送波受信用として使用するサブアンテナ5’の略コ字状のパターンの先端部の折返し水平線条5c’を2本線とし、AM放送波受信用アンテナ4の上部から4番目の水平線条の右側先端部の一部を前記2本の折返し水平線条5c’によって挟むようにして近接させ容量結合したものであり、AM放送波受信用アンテナの水平線条は5本としたが、各線条の長さは実施例2とほぼ同じである。
図4に示す実施例4は、実施例1の変形例であって、周波数が88~108MHz帯の北米・欧州・豪州向けFM放送波受信用として使用するサブアンテナ5’の略コ字状のパターンの先端部の折返し水平線条5c’を2本線とし、AM放送波受信用アンテナ4の最下部の水平線条の右側先端部の一部と、前記2本の折返し水平線条5c’、5c’の下方側とを近接させ容量結合したものであり、各線条の長さは実施例1とほぼ同じである。
Claims (9)
- 車両の後部窓ガラスの防曇用加熱線条の上部余白部に設ける車両用のガラスアンテナであって、
間隔を隔てて設けた複数本の水平線条と、該水平線条と直交する垂直線条を少なくとも2本離隔して設け、該垂直線条間で、かつ最上部の水平線条上、あるいは該最上部の水平線条の該部より引出線を介して設けた位置を第1の給電点とするAM放送波受信用のアンテナと、
前記AM放送波用アンテナの最上部の水平線条より上部に設けた第2の給電点より前記AM放送波受信用アンテナの最外周部の一部に沿って時計回り又は反時計回りの方向に延ばして前記AM放送波用アンテナを囲み、前記AM放送波受信用のアンテナの水平線条の少なくとも一部に近接かつ容量結合するようにしたFM放送波受信用アンテナとを含む、車両用のガラスアンテナ。 - 前記FM放送波受信用アンテナが、第2の給電点より水平方向に延ばした第2の水平線条が、前記AM放送波受信用のアンテナの水平線条に近接かつ容量結合し、さらにその先端より前記AM放送波受信用のアンテナの複数本の水平線条の外側に沿って略垂直方向又は円弧状に延ばした第2の垂直線条を少なくとも有するL字状、又はコ字状のエレメントとしたことを特徴とする請求項1記載の車両用のガラスアンテナ。
- 前記FM放送波受信用アンテナの先端部を折返した折返し水平線条を1本又は2本とし、AM放送波受信用の水平線条の先端部に近接かつ容量結合させることを特徴とする請求項1または2記載の車両用のガラスアンテナ。
- 前記第1の給電点を挟み、その両側に設けた2つの第2の給電点のそれぞれより前記FM放送波受信用アンテナを別々に2系統設け、該2系統のそれぞれをAM放送波受信用アンテナの最外周部に、時計回りと反時計回りに延ばし、ダイバーシティ受信させるようにしたことを特徴とする請求項1乃至3のいずれか一つに記載の車両用のガラスアンテナ。
- 前記AM放送波受信用アンテナの水平線条を、前記防曇用加熱線条の水平線条に近接させて容量結合するようにしたことを特徴とする請求項1乃至4のいずれか一つに記載の車両用のガラスアンテナ。
- 前記防曇用加熱線条のバスバーの上端部より上方に延ばした補助垂直線条が、前記FM放送波受信用アンテナの少なくとも第2の垂直線条の外側に沿って近接し、容量結合するようにしたことを特徴とする請求項1乃至5のいずれか一つに記載の車両用のガラスアンテナ。
- 前記AM放送波受信用のアンテナの第1の給電点よりAMラジオ放送波用のアンプを介してチューナーに接続し、FM放送波受信用のアンテナの第2の給電点よりアンプやインピーダンスマッチング回路を介さず直接チューナーに接続させることを特徴とする請求項1乃至6のいずれか一つに記載の車両用のガラスアンテナ。
- 前記第2の給電点から延ばしたFM放送波受信用アンテナの先端までの第1の水平線条長さとして、周波数が76~90MHz帯の日本国内向けFM放送波受信用アンテナとする時には200~500mmとし、周波数が88~108MHz帯の北米・欧州・豪州向けFM放送波受信用のアンテナとする時には150~400mmとして、該FM放送波受信用のアンテナの第2の水平線条または折返し水平線条と、前記AM放送波受信用のアンテナの水平線条とが互いに近接し容量結合する部分の各水平線条の合計長さ、および該部分の線条の間隔を、それぞれ、周波数が76~90MHz帯の日本国内向けFM放送波受信用アンテナとする時には200~400mm、2~30mm、周波数が88~108MHz帯の北米・欧州・豪州向けFM放送波受信用のアンテナとする時には、150~400mm、2~30mmとしたことを特徴とする請求項1乃至6のいずれか一つに記載の車両用のガラスアンテナ。
- 前記防曇用加熱線条の複数本の水平線条を横切るように設けた垂直線条を少なくとも2本設けたことを特徴とする請求項1乃至8のいずれか一つに記載の車両用のガラスアンテナ。
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US12/516,160 US8330663B2 (en) | 2008-09-16 | 2008-09-16 | Glass antenna for vehicle |
EP08872497A EP2214254A4 (en) | 2008-09-16 | 2008-09-16 | GLASS ANTENNA FOR VEHICLE |
PCT/JP2008/066667 WO2010032285A1 (ja) | 2008-09-16 | 2008-09-16 | 車両用ガラスアンテナ |
CN200880001371.4A CN102017293B (zh) | 2008-09-16 | 2008-09-16 | 车辆用玻璃天线 |
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EP2343773B1 (en) * | 2008-10-02 | 2018-03-07 | Central Glass Company, Limited | Vehicular glass antenna |
US8564489B2 (en) | 2009-06-16 | 2013-10-22 | Asahi Glass Company, Limited | Glass antenna and window glass for vehicle |
JP5281962B2 (ja) * | 2009-06-16 | 2013-09-04 | 旭硝子株式会社 | 車両用ガラスアンテナ及び車両用窓ガラス |
WO2012153664A1 (ja) | 2011-05-12 | 2012-11-15 | 旭硝子株式会社 | ガラスアンテナ及び窓ガラス |
EP3086476B8 (en) * | 2013-12-20 | 2019-07-24 | AGC Inc. | Antenna system |
US9653792B2 (en) | 2014-02-03 | 2017-05-16 | Pittsburgh Glass Works, Llc | Window antenna loaded with a coupled transmission line filter |
USD760205S1 (en) * | 2014-03-28 | 2016-06-28 | Lorom Industrial Co., Ltd. | Antenna for glass |
JP6481377B2 (ja) * | 2015-01-14 | 2019-03-13 | セントラル硝子株式会社 | ガラスアンテナ及び窓ガラス |
JP2017005354A (ja) * | 2015-06-05 | 2017-01-05 | 旭硝子株式会社 | 車両用ガラスアンテナ及び車両用アンテナを備えた後部窓ガラス |
JP2017175290A (ja) * | 2016-03-22 | 2017-09-28 | 旭硝子株式会社 | バックドア、及びガラスアンテナ |
JP6390666B2 (ja) * | 2016-06-03 | 2018-09-19 | マツダ株式会社 | ガラスアンテナ |
US10985438B2 (en) * | 2016-07-01 | 2021-04-20 | Nippon Sheet Glass Company, Limited | Vehicle window glass |
JP6879744B2 (ja) * | 2017-01-11 | 2021-06-02 | 日本板硝子株式会社 | 車両用窓ガラス |
EP3361563B1 (en) * | 2017-02-14 | 2020-10-07 | AGC Inc. | Glass antenna and window glass for vehicle |
JP2023023135A (ja) * | 2021-08-04 | 2023-02-16 | Agc株式会社 | 車両用窓ガラス |
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- 2008-09-16 US US12/516,160 patent/US8330663B2/en not_active Expired - Fee Related
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US20110043419A1 (en) | 2011-02-24 |
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