DE69922112T2 - Slice antenna assembly for an automobile - Google Patents

Description

The The present invention relates to a glass antenna assembly for a Automobile that is suitable to receive signals in, for example, a long-wave or long-wave broadcasting band (LW band) (150-280 kHz), a medium wave broadcast band (MW band) (530-1630 kHz), an FM broadcast band of Japan (76 - 90 MHz), an FM radio band of the USA (88 - 108 MHz), etc., which of high sensitivity, low noise and low Cost is.

As a glass antenna assembly for an automobile capable of improving the sensitivity by using resonance, a glass antenna assembly for an automobile has been proposed, as shown in FIG 7 (JP-A-4-53070).

In this conventional example is an anti-fogging unit 90 , including heating strips 2 and conductor tracks or busbars 15a . 15b . 15c on a glass pane 1 provided a rear window of a car, in which case the conductor track 15a in a lower section and the track 15b in an upper portion on a left side of the defogger 90 is provided. The lower track 15a is connected to the automobile body as the earth and the upper trace 15b is with an anode of a Gleichstromleistungs- or supply source 10 connected. A supplied current flows from the upper trace 15b through the track 15c , which is provided on a right side, to the lower trace 15a in a canal-like shape. The defogging unit, which in 7 is shown, is in a so-called channel-like shape.

In the glass antenna assembly, which in 7 is shown is a choke coil 9 between the tracks 15a . 15b and the DC power source 10 for the defogging unit 90 connected, and by increasing the impedance of the choke coil 9 in a high frequency band range, a direct current is allowed from the DC power source 10 to the defogger 90 However, a current in the high-frequency band area, such as a broadcast band area or the like is blocked, whereby the defogging unit 90 is used as an antenna.

Further, a parallel resonance by the stray capacitance to ground (hereinafter referred to simply as the stray capacitance) of the defogging unit becomes 90 , a coil 71 and the choke coil 9 is generated in a medium wave broadcast band, and a received signal in the medium wave broadcast band becomes common with a coil 72 , a capacitor 73 and a resistance 74 passed through. reference numeral 11 denotes a capacitor to cut off noise. In the conventional example, such a construction as in 7 An attempt has been made to improve sensitivity and reduce noise.

However, when such a conventional glass antenna array was used to receive signals in a long-wavelength broadcast band, generating a parallel resonance in the long-wavelength broadcast band, the inductance values of the coil were 71 and the choke coil 9 correspondingly high, such as 5 to 20 mH. Dement speaking was the dimension of each coil 71 and the choke coil 9 big, which did not fulfill a requirement of miniaturization. Furthermore, it was necessary to have thicker and longer conductive lines for the coil 71 and the choke coil 9 to use, which caused high production costs.

EP-A-0 856 904, which is the preamble of claim 1 of the present Disclosed a disc antenna assembly for an automobile, comprising a first and a second antenna conductor. A first resonance is due to the impedance of the first antenna conductor and the impedance of the first coil is generated as resonance elements or generated, and the second resonance is due to the impedance of the second Antenna conductor and the inductance of the second coil as resonance elements generated. The first antenna conductor is configured to be received of high-frequency band signals, and second Antenna conductor is designed to receive signals a low frequency band to be suitable.

It is an object of the present invention above mentioned Disadvantages of conventional technology to eliminate and a glass antenna assembly for a Automobile available to ask what the size and cost can reduce and which of high sensitivity and low noise is.

This object is met by a glass antenna array having the features disclosed in An Claim 1 are disclosed. Preferred embodiments are defined in the dependent claims.

In accordance with a preferred embodiment of the invention is a glass antenna assembly for a Automobile available provided, wherein an anti-fog unit of an electric heating, the Heating strips and conductor tracks or busbars for supplying a Current to the heating strips, and an antenna conductor a glass pane available placed in a rear window of a Automobile is used, and a choke coil with at least one between a track and a DC power source and connected between a track and the automobile body as the earth or connected, wherein the glass antenna device characterized characterized in that a Coil for a first resonance available is placed; generates a first resonance by a resonance element is generated, which the impedance of the antenna conductor and the inductance the coil for the first resonance comprises; a second resonance is generated by a resonance element, which is the Impedance of the defogging unit and the inductance of the choke coil comprises; a signal in at least one longwave broadcast band passing through the defogging unit is received is supplied to a receiver; a signal in at least one FM broadcast band passing through the antenna conductor is received, the receiver supplied becomes; the resonance frequency of the first resonance and the resonance frequency of the second resonance are determined so that the sensitivity of signals is increased in the long-wave broadcast band, and a capacitor for the second resonance electrically between the defogger and the anti-mobile body as connected to the earth.

In accordance with a second embodiment of the present invention is a Slice antenna arrangement for an automobile is available wherein an anti-fogging unit of the electric heating, the heating strips and conductor tracks or busbars for supplying a Includes electricity to the heating strips, and provides an antenna conductor on a glass sheet, in a back window an automobile is used, and a choke coil with at least one between a trace and a DC source and connected between a track and the automobile body as the earth or is connected, so that a Signal in a long-wave radio band and a signal in one Frequency band which is higher in frequency than the long-wave Broadcasting, are received, wherein the glass antenna device characterized in that a first resonance and a second resonance are generated or generated; a capacitor for a second resonance available is placed; the inductance the choke coil, the impedance of the defogger and the capacity of the capacitor for contain the second resonance as resonance elements for the second resonance are; the resonance frequency of the first resonance and the resonance frequency the second resonance are determined so that the sensitivity of signals is increased in the long-wave broadcast band, and the capacitor for the second resonance electrically between the defogger and the automobile body as connected to the earth.

Furthermore, will be in accordance With a third embodiment of the present invention, a glass antenna assembly for a Automobile available wherein an anti-fogging unit of the electric heating, the heating strip and traces for supplying a current to the heating strips and an antenna conductor provided on a glass sheet are in a backward disk an automobile are used, and a choke coil with at least one between a trace and a DC power source and so connected between a trace and the automobile body as the earth is that one Signal received by the antenna conductor is supplied to a receiver, the pane antenna arrangement being characterized that one Coil for a first resonance electrically between the antenna conductor and the receiver by interposing or switching a line and / or a Circuit element is connected or connected; a capacitor for one second resonance electrically with at least one between the defogging unit and the automobile body as the earth and between the antenna conductor and the automobile body as the earth by interposing or switching a line and / or a circuit or circuit element is connected.

In the drawings:

is 1 a structural diagram of an embodiment of the glass antenna assembly for an automobile according to the present invention;

is 2 a structural diagram of another embodiment of the glass antenna assembly for an automobile according to the present invention;

is 3 an equivalent circuit diagram for explaining the function of an antenna conductor 3 . an anti-fogging unit 90 and a resonance circuit 6 in the glass antenna array used in 1 is shown;

is 4 a circuit diagram showing a modified example of the resonant circuit 6 shows;

is 5 a characteristic diagram of frequency versus sensitivity in a long-wave broadcast band in Example 1, 2 and 3;

is 6 a characteristic diagram of frequency versus sensitivity of signals in and around a long-wave broadcast band and a medium wave broadcast band in Example 1, 2 and 3;

is 7 a structural diagram of a conventional glass antenna assembly for an automobile;

is 8th a circuit diagram showing a formation of a resonant circuit 6 shows that of the in 1 shown is different;

is 9 a characteristic diagram of frequency sensitivity with of signals in and around a long-wave broadcast band and a medium-wave broadcast band in Example 4;

is 10 a characteristic diagram of frequency vs. sensitivity of signals in and around a long-wave broadcast band and a medium-wave broadcast band in Example 5;

is 11 a characteristic diagram of frequency vs. sensitivity of signals in and around a long-wave broadcast band and a medium-wave broadcast band in Example 6;

is 12 a characteristic diagram of frequency versus sensitivity of signals in and around a long-wavelength broadcast band and a medium wave broadcast band in Example 7;

is 13 a characteristic diagram of frequency vs. sensitivity of signals in and around a long-wave broadcast band and a medium wave broadcast band in Example 8; and

is 14 a characteristic diagram of frequency versus sensitivity of signals in and around a long-wave broadcast band and a medium-wave broadcast band in Example 9.

A detailed description of preferred embodiments of the present invention The invention will be described with reference to the drawings.

1 FIG. 14 is a diagram showing the basic structure of a structure of the glass antenna device for an automobile of the present invention, wherein a glass sheet. FIG 1 is used for a rear window of an automobile. In 1 denotes reference numeral 2 Heating strip, number 3 an antenna conductor, number 4 a power supply point for the antenna conductor 3 , Numbers 5a . 5b designate conductor tracks or busbars, number 6 denotes a resonant circuit, number 7 a recipient, number 7a a cable, number 31 a coil for a first resonance, number 32 a capacitor for a second resonance, number 42 a bypass capacitor, numbers 45 . 48 denote damping resistors, number 47 a resistor to reduce noise in the automobile, such as engine noise, number 50 a capacitor for interrupting a direct current, number 52 a high frequency choke, number 90 an anti-fogging unit and number 91 a power supply point provided at one end of an outgoing line connected to the defogger 90 connected is. In the explanation described below, directions are indicated as directions on the drawings unless it is specifically stated.

In 1 are the defogging unit 90 the type of electrical heating that the heating strips 2 and tracks 5a . 5b for supplying a current to the heating strips 2 and the antenna conductor 3 on the glass 1 provided in a rear window of an automobile. A choke coil 9 is between the track 5b and a DC power source 10 and between the track 5a and the automobile body as the ground from the viewpoints of improving the sensitivity and reducing noise. However, the choke coil can 9 either between the track 5b and the DC power source 10 or between the track 5a and be connected to the automobile body as the earth.

Received signals in the antenna conductor 3 and the defogging unit 90 become the recipient 7 fed. The coil for the first resonance 31 is electrically between the antenna conductor 3 and the receiver 7 by temporarily storing a line and the capacitor 50 connected. The way of connecting the coil for the first resonance 31 is not specifically limited to training, as in 1 and instead, the first resonance coil may be electrically connected between the antenna conductor 3 and the receiver 7 be connected by an intermediate storage or switching of at least one line and a circuit element.

In this specification, the circuit element includes any element suitable for a semiconductor device and a circuit such as a capacitor, a coil, a resistor, a diode, a transistor or the like. Further, the line means an electrical connection with a wire or an electrical connection to a conductor pattern or a connector provided on a circuit substrate. In 1 closes "the antenna conductor 3 and the defogging unit 90 which are electrically connected ", resulting from a capacitive coupling of the antenna conductor 3 and the defogging unit 90 is available, the line off, as defined above. The definition is also applicable to other training.

In 1 is the capacitor for a second resonance 32 electrically between the defogger 90 and the automobile body connected to earth by a wire and the resistor 48 are or are interposed. The path of a connection of the capacitor for the second resonance 32 is not specifically limited to training, as in 1 is shown, and instead, the capacitor for the second resonance 32 electrically between the defogger 90 and the automobile body as the earth by interposing at least one of a line and a circuit element.

3 FIG. 12 is an equivalent circuit diagram for explaining the principle of the glass antenna array as shown in FIG 1 is shown, with the resistors 45 . 47 and 48 have been omitted for a simplification of the explanation; the section of resistance 45 is open and the sections of the resistors 47 and 48 are shorted.

In 3 E1 denotes a power source for the antenna conductor 3 , E2 denotes a voltage supply source for the defogger 90 , Reference number 33 denotes the stray capacitance of the antenna conductor 3 , Reference number 34 indicates the stray capacitance of the defogger 90 and reference numerals 35 indicates the stray capacitance of the cable. When the antenna conductor 3 near the defogger 90 is arranged to have a capacitive coupling relationship, the small capacitance due to the capacitive coupling is in parallel with the high frequency choke coil 52 connected or connected.

The antenna conductor 3 is preferably used to mainly receive or receive signals in an FM broadcast band. In this case, it is preferable to determine the length of a conductor and the shape of the conductor so that good signal reception performance can be obtained in the FM broadcast band. Furthermore, the antenna conductor 3 for receiving signals in a medium wave broadcast band, a shortwave broadcast band, a longwave broadcast band, a TV VHF band, a TV UHF band, and a telephone.

The defogging unit 90 is used to mainly receive signals in a long-wave broadcast band. Since frequencies in the long-wave broadcast band are nearly frequencies in the medium-wave broadcast band, the defogging unit 90 for receiving signals in the long-wave broadcast band and in the medium-wave broadcast band. Although the defogging unit 90 has a function for receiving signals in a shortwave broadcasting band, an FM broadcasting band, a TV-VHF and a TV-UHF band, and a telephone uses the glass antenna assembly for an automobile disclosed in U.S. Pat 1 is shown, such a function is not.

The sensitivity of signals is improved by generating resonance in two sections. For the first resonance are the impedance of the antenna conductor 3 and the inductance of the coil for the first resonance 31 included as resonance elements.

The impedance of the antenna conductor 3 is the impedance of the side of the antenna conductor 3 , seen from the power supply point 4 , The impedance of the antenna conductor 3 is mainly the stray capacity 33 , which is generally 10 - 100 pF.

The resonant frequency of the first resonance can be adjusted by placing a capacitance element in parallel between the stray capacitance 33 and the automobile body is connected as the earth. This capacitance element may be a resonance element for the first resonance. The automobile body as the ground means an electrically conductive portion of the automobile body, which is usually made of metal.

As the antenna conductor 3 and the defogging unit 90 are electrically connected, affects the impedance of the defogger 90 the first resonance, and it may be a resonance element for the first resonance.

The impedance of the defogger 90 is the impedance of the side of the defogger 90 , seen from the power supply point 91 , The impedance of the defogger 90 is mainly the stray capacity 34 which is usually 50-300 pF.

The stray capacitance of a wire, which is in the neighborhood of the coil for the first resonance 31 extends, and the stray capacitance of the cable 7a , which is connected between the glass antenna and the receiver, also affect the first resonance and they can be resonance elements for the first resonance.

When the resonant circuit 6 on the glass 1 is provided for a rear window of the automobile, or the resonance circuit 6 in the vicinity or near the glass pane 1 is provided for a rear window of an automobile, the length of the cable 7a usually several meters, because the receiver 7 is usually provided on a front portion of the automobile, and the capacity value of the stray capacity 35 is usually 50 - 300 pF.

There may be an impedance match between the antenna conductor 3 and the receiver side by applying a new circuit element in the resonant circuit 6 is made available. The coil for the first resonance 31 is generally about 10 μH - 1 mH in order to improve the sensitivity in a long-wave broadcast band. In this range, 50-500 μH are preferable, and 65-350 μH are more preferable.

In the present invention, the sensitivity of signals in a long-wavelength broadcast band is improved by generating the second resonance. When the resonance frequency for the second resonance is determined to improve the sensitivity in the long-wavelength broadcast band and when the capacitance forming the resonance element for the second resonance is only the stray capacitance 34 is, it is necessary, the inductance of the choke coil 9 to increase. In this regard, the capacitor is for the second resonance 32 added to be a resonance element for the second resonance, whereby the inductance of the choke coil 9 can be made relatively small.

The inductance of the choke coil 9 is preferably in a range of 0.5 to 5.0 mH. In this range, the resonance frequency of the second resonance may be the resonance frequency for improving the sensitivity in the long-wave broadcast band, and the choke coil 9 can be minimized. A range of 1.0-3.0 mH is more preferable, and a range of 1.5-3.0 mH is particularly preferable.

In 1 are the impedance of the choke coil 9 , the impedance of the defogger 90 and the capacitance of the capacitor for the second resonance 32 as main resonant elements for the second resonance, and they may be the main resonant elements. The capacitor for the second resonance 32 which is commonly used is about 10 - 5,000 pF.

However, taking into account that the stray capacitance 34 Generally, about 50-200 pF is a preferred range of the capacitance value of the second resonance capacitor 32 from 50 to 1,200 pF. In this range, the inductance of the choke coil 9 Generally, it may be 5.0 mH or less, and the resonance frequency of the second resonance may be the frequency for improving the sensitivity in the long-wavelength broadcast band. A more preferred range is 100-500 pF.

The resistance 48 serves to adjust the attenuation in the second resonance and a preferred range of the resistance of the resistor 48 is 200 Ω - 25 kΩ. In this range, the difference between the highest sensitivity and the lowest sensitivity in the long-wavelength broadcast band may generally be 10 dB or less. The resistance 48 also has a function for adjusting the coupling between the antenna conductor 3 and the defogging unit 90 , and accordingly, it is preferable that resistance 48 to provide. The presence of the resistance 48 can reduce the sensitivity in the long-wave broadcast band compared with the absence of the resistor 48 improve.

In order to adjust the damping of the second resonance, a resistor can be connected in parallel with the capacitor or the capacitance of the second resonance 32 be connected, or a resistor can with the inductor 9 be connected, although such elements in 1 and 2 not shown.

As the antenna conductor 3 and the defogging unit 90 are electrically connected, further affects the impedance of the antenna conductor 3 also the second resonance, and it can be a resonance element for the second resonance. Furthermore, the stray capacitance of a line around the antenna conductor 3 , the stray capacitance of a line around the defogger 90 , the stray capacitance of a line around the capacitor for the second resonance 32 and the like also affect the second resonance and they may be resonance elements for the second resonance. It also affects the stray capacitance of the cable 7a between the output terminal of the resonant circuit 6 and the receiver is connected, the second resonance.

In 1 For example, the first resonance is a series resonance and the second resonance is a parallel resonance, which is preferably generated from the viewpoint of improving the sensitivity. In the present invention, however, the first resonance is not limited to a series resonance and the second resonance is not limited to a parallel resonance. Accordingly, the first resonance may be a parallel resonance and the second resonance may be a series resonance.

In 1 For example, the resonance frequency of the first resonance and the resonance frequency of the second resonance are determined to be such as to improve the sensitivity of signals in the long-wavelength broadcast band. In particular, the frequency for parallel resonance as the second resonance is preferably 100-180 kHz, more preferably 120-150 kHz.

It also divides into 1 the high frequency choke coil 52 as an inductance element generally with respect to high frequency, the antenna conductor 3 from the defogging unit 90 in an FM broadcast band, and works to improve the sensitivity in the FM broadcast band without the effective length of the conductor of the antenna conductor 3 to change.

Furthermore, in one case, the high frequency choke coil 52 is not provided and the location of the high-frequency choke coil 52 is shorted, the self-resonant frequency of the choke coil 9 low and generally shows a capacitive property in the FM broadcast band. Accordingly, received signals in the FM broadcast band leaked in the antenna conductor 3 are excited to the automobile body as the earth. Therefore, the high frequency choke coil 52 provided to prevent leakage. In other words, the high-frequency choke conducts 52 Signals having frequencies in the long-wavelength broadcast band and functioning as a filter circuit which blocks or attenuates signals; have the frequencies in the FM broadcast band. Furthermore, the high frequency choke coil conducts 52 also frequencies in a medium wave broadcast band.

It is preferable to use a filter circuit by using the high-frequency choke coil 52 to train in 1 as the circuit structure is simple and cheap. However, the filter circuit is not limited to use of such a coil and may be composed of another circuit structure. The way of connecting the filter circuit is not limited to that described in US Pat 1 is shown, and the filter circuit can electrically between the antenna conductor 3 and the defogging unit 90 be connected by an interposition of at least one line and a circuit element.

Further, in a case that signals in a long-wavelength broadcast band and in an FM broadcast band are included as signals in a broadcast band to be received, the inductance value of the high-frequency choke coil 52 preferably in a range of 0, 1 - 100 μH. When the inductance value of the high-frequency choke coil 52 is within the range of 0.1 - 100 μH, the sensitivity in the FM broadcast band is improved to 0.2 dB or more in comparison with a case outside the range of 0.1 - 100 μH. From the viewpoint of improving the sensitivity in the FM broadcast band, the high-frequency choke coil 52 preferably, an inductance value of a range of 0.3-20 μH, more preferably a range of 0.8-4.8 μH.

With respect to the self-resonant frequency f _{R of} the high-frequency choke coil 52 to improve of the sensitivity in the FM broadcast band, a relationship of f _H / 15 ≦ f _R ≦ 3f _L between the highest frequency f _{H of} the FM broadcast band and the lowest frequency f _{L of} the FM broadcast band should be satisfied or satisfied. Filling a relationship of f _H / 9 ≦ f _R ≦ 2f _L is more preferable, and f _H / 3.6 ≦ f _R ≦ 1.85f _L is particularly preferable.

In 1 it is preferred for the antenna conductor 3 and the defogging unit 90 that they have no capacitive relationship. If they have a capacitive coupling relationship, received signals in the FM broadcast band present in the antenna conductor 3 are excited, susceptible, to the automobile body as the ground by the defogger 90 and the choke coil 9 to lick. To the antenna conductor 3 and the defogging unit 90 To prevent them from having a capacitive coupling relationship should be the shortest distance between the antenna conductor 3 and the defogging unit 90 generally 10 mm or more. When the shortest section is 10 mm or more, the sensitivity of the FM broadcast band is improved by 0.5 dB or more as compared with a case where the shortest distance is less than 10 mm. More preferably, the shortest distance should be 20 mm or more. When the shortest distance is 20 mm or more, the sensitivity in the FM broadcast band is improved by 0.5 dB or more in comparison with a case that the shortest distance is less than 20 mm.

The above-mentioned condition of the shortest distance between the antenna conductor 3 and the defogging unit 90 is generally applied to a case that the length of portions substantially parallel in the antenna conductor 3 and the defogging unit 90 extend, 100 mm or more.

In a case that the shortest distance between the antenna conductor 3 and the defogging unit 90 less than 10 mm, since the dimension is in a vertical direction of the glass sheet 1 for a rear window of an automobile is small, it is preferable to high-frequency choke coils 12a . 12b between the track 5a and the automobile body as the earth and between the track 5b and the automobile body as the earth and connect, as in 2 is shown. This is because signals received in the FM broadcast band present in the antenna conductor 3 are blocked by such a high-frequency choke coil to prevent the signals from leaking to the automobile body as the earth.

2 shows another embodiment of the glass antenna assembly for an automobile, which in 1 is shown, wherein the glass antenna array is suitable for diversity signal reception. In 2 denotes reference numeral 53 a capacitor, reference numeral 60 a high-frequency choke coil, symbol t ₁ a first input terminal of the receiver 7 and symbol t ₂ a second input terminal of the receiver 7 , The recipient 7 is adapted to select a stronger received signal in an FM broadcast band at either the first input terminal t ₁ or the second input terminal t ₂ .

The capacitor 53 is provided in accordance with the requirement which functions to block or attenuate received signals in a long-wavelength broadcast band. The capacitance value of the capacitor 53 is preferably in a range of 10 - 500 pF, more preferably 30 - 150 pF. When the capacitance value of the capacitor 53 10 pF or more, the sensitivity in the FM broadcast band at the second input terminal t ₂ is improved by 1 dB or more in a case that the capacitance value is smaller than 10 pF. When the capacitance value of the capacitor 53 500 pF or less, the sensitivity in the long-wavelength broadcast band at the first input terminal t ₁ is improved by 1 dB or more in a case that the capacitance value exceeds 500 pF.

Received signals in the FM broadcast band can pass through the capacitor for the second resonance 32 to the automobile body as the ground, so that the sensitivity in the FM broadcast band is reduced. To avoid such a disadvantage, the high-frequency choke coil 60 in series with the capacitor for the second resonance 32 be connected. The high frequency choke coil 60 , which has about 0.1-100 μH, is commonly used.

In the glass antenna assembly for an automobile used in 2 is shown, it is preferred that the high frequency choke coils 12a . 12b between tracks and the inductor 9 to connect or connect. The reason is the following. In the glass antenna assembly, which in 1 are received signals in the FM broadcast band which are in the defogger 90 are energized, not used. On the other hand, in the glass antenna array shown in FIG 2 4, received signals in the FM broadcast band excited in the defogger are used at the second input terminal t ₂ . Accordingly, the choke coils serve 12a . 12b to receive received signals in the FM Broadcasting band operating in the defogging unit 90 are aroused to prevent licking to the automobile body as the earth.

In 2 is the second input terminal t _{2 of} the receiver 7 from the inside of the resonant circuit (a left end of the capacitor 53 is with a point in the resonance circuit 6 connected). However, the second acceptance point of the second input terminal t _{2 is} not on the inside of the resonance circuit 6 limited, but he can from any point of the defogger 90 be removed. Furthermore, an antenna conductor, which of the antenna conductors 3 is separated, may be provided in a room which is lower in position than the defogger 90 is to perform a diversity signal reception between the first input terminal t ₁ and the other antenna conductor.

Of the Reason why a resonance in the two sections in the present Invention is generated or generated is that a wider frequency band range of an unreceived signal by only a single resonance can be covered. Accordingly, in the present invention a long-wave broadcast band divided into two sections and the divided areas are defined by the two sections of the Divided resonance, reducing the sensitivity of the received signals flattened or balanced. When signals in a medium wave broadcast band additionally are to be received to the long-wave broadcast band is or will a frequency band range, which the long-wave broadcast band and the medium wave broadcast band covering, divided by two sections of a resonance, causing the Sensitivity of signals in such a frequency band range flattened. Flattening or balancing the sensitivity means that the Difference between the highest Sensitivity and the lowest sensitivity in the long-wave Broadcasting band area is made small.

4 FIG. 12 is a circuit diagram showing a modified configuration of the resonance circuit. FIG 6 shows. In 4 reference numbers 41 . 44 and 50 Capacitors for blocking a direct current, reference sign denotes 42 a bypass capacitor, designated reference numeral 43 a capacitor for blocking a direct current or for coupling, denote reference numerals 45 . 48 and 49 Damping resistors, designated reference numeral 55 a resistor for setting a coupling and called number 56 a capacitor for setting a coupling or connection.

In the resonant circuit in 4 be in the defogging unit 90 received signals to a side of the receiver through the resistor 47 , the high-frequency choke coil 52 and the capacitor 43 transfer. When the antenna conductor 3 and the defogging unit 90 have a capacitive coupling relationship, however, receive signals of the defogger 90 transmitted to the receiver side by the closed capacity.

The bypass capacitor 42 is provided according to the requirements. When received signals in the FM broadcast band are blocked by the first coil, the bypass capacitor allows it 42 Signals in the FM broadcast band that they thereby pass to the receiver side. The capacitors 43 . 56 Serve to the coupling between the antenna conductor 3 and the defogging unit 90 and they are provided according to the requirements. The resistors 45 . 48 . 49 and 55 , which adjust a flattening of the sensitivity, are provided according to the requirement. In addition, a capacitor may be provided for a resonance adjustment.

The capacitors 41 . 44 . 50 and 54 are provided according to the requirement. When used, a capacity of 100 pF - 50 μF is commonly used. The bypass capacitor used 42 is generally 1 - 1,000 pF. The used capacitor 43 is generally 5 - 500 pF. The resistors 45 . 49 and 55 which are used are generally 50 Ω - 100 kΩ.

Further, there is a possibility that a supply wire for supplying a direct current from the DC power source 10 to the defogger 90 a noise of automobiles, such as engine noise picks up to effect a deterioration in the S / N ratio. The resistance 47 is provided according to the requirement which prevents the deterioration of the S / N ratio. In particular, it functions to prevent the deterioration of the S / N ratio in a low-frequency range in a long-wavelength broadcast band. It has the resistance 47 the function to reduce noise of an automobile such as engine noise.

The resistance of the resistor 47 is preferably 10 Ω-1 kΩ, more preferably 50-500 Ω. When the resistance of the resistor 47 10 Ω - 1 kΩ, is the S / N ratio of Sig in the long-wavelength broadcast band is improved by 1 dB or more as compared with a case outside this range. When the resistance of the resistor 47 50-500 Ω, the S / N ratio in the long-wavelength broadcast band is improved by 1 dB or more as compared with a case outside this range.

As described above, the capacitors are 41 . 42 . 43 . 44 . 50 , and 54 and the resistors 45 . 47 . 48 . 49 and 55 in 4 provided according to the requirement, or they may be omitted. This implies the omission of the capacitors 42 . 56 and 44 and the omission of the resistors 45 . 49 and 55 an opening, and the omission of capacity 41 . 43 . 50 and 54 and the omission of the resistors 47 and 48 implies a short circuit.

8th Fig. 10 is a circuit diagram of a modified example of the resonance circuit 6 , in the 1 is shown. In 8th are the antenna conductor 3 and the defogging unit 90 omitted. In 8th Symbols A, B, C and D indicate points on lines. In 1 is an end (point C) of the second resonance capacitor 32 , which is opposite the automobile body than the ground, electrically with the power supply point 91 connected by a line. In 8th On the other hand, point C is electrical with one end (point B) of the capacitor 50 which is opposite the antenna conductor 3 is connected by means of a line. In other words, the capacitor is for the second resonance 32 electrically between the antenna conductor 3 and the automobile body connected as the earth by means of a conduit in which the capacitor 50 and the resistance 48 are interposed. Connecting the capacitor for the second resonance 32 is not on the in 8th shown embodiment, and instead, the capacitor for the second resonance 32 electrically between the antenna conductor 3 and the automobile body as the ground by interposing at least one line and a circuit element. Further, the point C may be electrically connected to the point D by interposing at least one line and a switching element.

In terms of connection, as in 8th shown are when the resistance of the resistor 47 is as small as several tens of Ω or less, the function of the first resonance and the function of the second resonance in the same manner as those of the resonance circuit 6 in 1 , and all in terms of 1 conditions described are on the resonant circuit 6 in 8th applicable. However, the resonance circuit is 6 in 1 easy at reducing noise, because the resistance of the resistor 47 can be increased, and it is therefore the resonant circuit 6 in 1 preferably instead of the resonant circuit 6 in 8th ,

In 2 are or are the choke coil 9 and the high frequency choke coils 12a . 12b between the tracks 5a . 5b and the DC power source 10 for the defogging unit 90 used to thereby reduce the impedance of the choke coil 9 and the impedance of the high frequency choke coil 12a . 12b in the broadcast band area, thereby providing DC power from the DC power source 10 to the defogger 90 is allowed to flow, and a stream is blocked to the broadcast band area.

So are the heating strips 2 the defogging unit 90 and the tracks 5a . 5b from the automobile body as the earth with respect to high-frequency signals by means of the choke coil 9 and the high frequency choke coil 12a . 12b isolated, whereby a stream of a received signal in the broadcast band, in the defogger 90 is excited, is prevented from flowing to the automobile body as the earth, and a stream of a received signal is supplied to the receiver without any leakage. The inductor used 9 is generally about 0.1 - 10 mH.

The high frequency choke coils 12a . 12b and the high frequency choke coil 60 Provide a high impedance in a high frequency band such as an FM broadcast band in a broadcast frequency band. Accordingly, a solenoid or a magnetic core is commonly used. Such elements show an inductive type of inductance in a high frequency band, such as an FM broadcast band, or in the vicinity of such a frequency band.

In a high frequency band, such as an FM broadcast band, the self-resonant frequency of the choke coil 9 low and the impedance of the choke coil 9 shows a capacitive property, thereby becoming a low impedance. In this case, the high-frequency choke coils function 12a . 12b as the choke coil 9 , The high frequency choke coils 12a . 12b which are commonly used are from 0.1 to 100 μH.

If the impedance of the choke coil 9 not a capacity property in a high-frequency band, As a FM radio band shows, and it shows a high impedance, the high frequency choke coils 12a . 12b unnecessary. Furthermore, if any coil or coils can perform both functions of the choke coil 10 and the high frequency choke coils 12a . 12b is exercised, such a coil or coils are used.

The defogging unit 90 , in the 1 and 2 is shown is in a trapezoidal shape. However, the defogging unit used in the present invention is 90 not limited to such a shape, and any shape, such as a substantially channel-like shape, as in 7 can be shown, for the defogger 90 of the present invention.

The antenna conductor 3 may be in a space of the upper, lower, left or right portion with respect to the defogger 90 in the glass pane 1 of the automobile window and the section is not on the in 1 shown limited. Furthermore, the number of antenna conductors in the glass pane 1 provided, not specifically limited.

The number of antenna conductors provided on an automobile other than the antenna conductor 3 , is not limited. Furthermore, the pane antenna assembly of the present invention has the function of diversity signal reception in common with an antenna device such as a pole antenna or other type of pane antenna device.

EXAMPLE

EXAMPLE 1

A glass panel for a rear window of an automobile was used and the glass antenna assembly as shown in FIG 1 shown was prepared. The resistance 47 and the capacitor 50 were not provided, and the sections according to the resistance 47 and the capacitor 50 were shorted. The capacitor 43 in 4 was provided. The circuit constants of elements used are shown in Table 1.

The length of the conductor and the shape of the conductor of the antenna conductor 3 were set so that signals could be received in an FM broadcast band. The distance between a lower portion of the antenna conductor 3 and the highest wire of the heating strips 2 was determined to be 21 mm. In this case, there was essentially no capacitive coupling between the antenna conductor 3 and the defogging unit 90 found.

A thick solid line in 5 Fig. 10 shows a frequency-sensitivity characteristic of a signal in the vicinity of a long-wavelength broadcast band. A thick solid line in 6 shows a frequency-sensitivity characteristic of a signal in the vicinity of a long-wavelength broadcast band or a medium-wave broadcast band. The sensitivity of a pole antenna of 870 mm length was about 67 dB at 100-2,100 kHz.

EXAMPLE 2

A glass antenna assembly was made in the same manner as in Example except that the resistance of the resistor 48 changed to 220 Ω. The frequency-sensitivity characteristics are indicated by thin solid lines in FIG 5 and 6 indicated.

EXAMPLE 3

A glass antenna array was fabricated in the same manner as in Example 1 except that the resistance of the resistor 48 was changed to 22 kΩ. The frequency-sensitivity characteristics are indicated by broken lines in FIG 5 and 6 indicated.

Table 1

EXAMPLE 4

A glass antenna array was fabricated in the same manner as in Example 1 except that the circuit constants were determined as shown in Table 2. The frequency-sensitivity characteristic of a signal in the vicinity of a long-wavelength broadcast band or a medium-wave broadcast band is in 9 shown.

Table 2

EXAMPLE 5

A glass antenna array was fabricated in the same manner as in Example 1 except that the circuit constants were determined as shown in Table 3. The frequency-sensitivity characteristic of a signal in the vicinity of a long-wavelength broadcast band or a medium-wave broadcast band is in 10 shown.

Table 3

EXAMPLE 6

A glass antenna assembly was constructed in the same way as in FIG 1 except that the circuit constants were determined as shown in Table 4. The frequency-sensitivity characteristic of a signal in the vicinity of the long-wavelength broadcast band or a medium-wave broadcast band is in 11 shown.

Table 4

EXAMPLE 7

A glass antenna array was fabricated in the same manner as in Example 1 except that the circuit constants were determined as shown in Table 5. The frequency-sensitivity characteristic of a signal in the vicinity of a long-wavelength broadcast band or a medium-wave broadcast band is in 12 shown.

Table 5

EXAMPLE 8

A glass antenna array was fabricated in the same manner as in Example 1 except that the circuit constants were determined as shown in Table 6. The frequency-sensitivity characteristic of a signal in the vicinity of a long-wavelength broadcast band or a medium-wave broadcast band is in 13 shown.

Table 6

EXAMPLE 9

A glass antenna array was fabricated in the same manner as in Example 1 except that the circuit constants were determined as shown in Table 7. The frequency-sensitivity characteristic of a signal in the vicinity of a long-wavelength broadcast band or a medium-wave broadcast band is in 14 shown.

Table 7

According to the present invention, the first resonance is generated by the impedance of the antenna conductor and the inductance of the first resonance coil as resonance elements, and the second resonance is generated by impedance of the anti-fogging unit and the inductance of the second resonance capacitor as resonance elements. Accordingly, the sensitivity of signals of a long-wavelength broadcasting band is excellent, since two resonance sections are used. Furthermore, the size of the choke coil 9 reduced and manufacturing costs can be reduced.

If a filter circuit electrically between the antenna conductor and the defogger is connected or connected to receive To block or attenuate signals in an FM broadcast band received signals in the FM broadcast band which are in the antenna conductor were aroused, licking to the automobile body as the earth, and a reduction in the sensitivity of signals in the FM Broadcasting band is small.

If Signals received in a long-wave broadcasting band can both the antenna conductor as well as the defogger unit are used, whereby the sensitivity in the long-wavelength broadcast band is excellent is. On the other hand, when receiving signals in an FM broadcast band, a effective length be used by only the antenna conductor, reducing the sensitivity in the FM broadcasting band is excellent.

Claims (5)

A glass antenna device for an automobile comprising: a window glass pane ( 1 ) which fits in a rear window opening of an automobile; an antenna conductor ( 3 ), which has an antenna impedance, which on the window glass pane ( 1 ) is provided; an anti-fogging unit ( 90 ) of an electrical heating type, which has an anti-fogging impedance, which on the window glass pane ( 1 ), the heating strips ( 2 ) and conductor tracks or busbars ( 5a . 5b ) for supplying a current to the heating strips ( 2 ) having; a choke coil ( 9 ) having an inductance connected to at least one between a conductor track ( 5a . 5b ) and a DC power source and between a conductor track ( 5a . 5b ) and the automobile body is connected to the earth; a coil ( 31 ) with an inductance; a receiver ( 7 ); a first resonant circuit comprising a first group of resonant elements comprising the slices causing the antenna device to oscillate at a first resonant frequency, the first group of resonant elements reflecting the impedance of the antenna conductor (FIG. 3 ) and the inductance of the coil ( 31 ); a capacitor ( 32 ) having a capacity; a second resonant circuit comprising a second group of resonant elements causing the glass antenna to oscillate at a second resonant frequency different from the first resonant frequency, the second group of resonant elements mainly controlling the inductance of the choke coil (10); 9 ), the impedance of the defogger ( 90 ) and the capacitance of the capacitor ( 32 ) for the second resonance; the inductance of the choke coil ( 9 ) from 0.5 to 5.0 mH, the impedance of the defogger ( 90 ) mainly comprises a stray capacity of 50 to 300 pF; a signal in at least one FM broadcast band passing through the antenna conductor ( 3 ), the recipient ( 7 ) and the impedance of the antenna conductor ( 3 ) mainly comprises a stray capacitance of 10 to 100 pF and the inductance of the coil ( 31 ) for the first resonance of 10 μH to 10 mH, the coil ( 31 ) for the first resonance electrically between the antenna conductor ( 3 ) and the recipient ( 7 ) is connected by interposing or switching a line and / or a circuit element; a high frequency choke coil ( 52 ) configured to attenuate a signal in an FM broadcast band electrically between the antenna conductor (10) 3 ) and the anti-fogging unit ( 90 ), characterized in that a signal in at least one long-wave radio band transmitted by the anti-fogging unit ( 90 ), the recipient ( 7 ) is supplied; the capacitor ( 32 ) electrically between the defogging unit ( 90 ) and the automobile body as the earth and / or between the antenna conductor ( 3 ) and the automobile body as the earth is connected by interposing a line and / or a circuit element; the capacity of the capacitor ( 32 ) ranges from 50 to 1200 pF; the frequency of the second resonance is from 120 to 150 kHz. A glass antenna device for an automobile according to claim 1, wherein a high frequency choke coil ( 60 ) in series with the capacitor ( 32 ) is connected for a second resonance. A glass antenna device for an automobile according to claim 1 or 2, wherein the second resonance is a parallel or parallel resonance is. A glass antenna device for an automobile according to any one of claims 1 to 5, wherein a resistor having a resistance of 200 Ω - 25 kΩ is interposed between the capacitor (3). 32 ) for the second resonance and the automobile body is connected to earth. A glass antenna device for an automobile according to one or more of claims 1 to 4, wherein a relation of f _H / 15 ≤ f _R ≤ 3f _L , where f _{R is} the self-resonant frequency of the high-frequency frequency choke coil ( 52 ), f _{H represents} the highest frequency of the FM broadcast band, and f _{L represents} the lowest frequency of the FM broadcast band.