JP2006270602A - Non-directional antenna - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a non-directional antenna which is almost non-directional in a horizontal plane, wide in a frequency range, excellent in workability for its mounting on a vehicle, and suitable for receiving broadcasting waves. <P>SOLUTION: The nondirectional antenna 10 receiving ground waves is composed of a loop-shaped element 10A provided to a front window 2 as a part formed of the dielectric material of a vehicle 1, and feeding points 11 and 12 of the loop-shaped element 10A located near the lateral pillars 3L and 3R as conductors constituting the vehicle 1. In this case, a passive element 10B formed of a conductor independent from the conductors that constitute the loop-shaped element 10A is arranged close to the loop-shaped element 10A so as to receive a circularly polarized waves. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to an omnidirectional antenna, and more particularly to a horizontal omnidirectional antenna for receiving radio waves such as broadcasts in a moving body such as an automobile.

  2. Description of the Related Art Conventionally, an antenna that enables reception of radio waves while moving is mounted on a vehicle (moving body) such as an automobile. In general, radio waves received by vehicles have been mainly AM radio wave (MW), FM radio and TV ultra-high frequency (VHF) and ultra-high frequency (UHF) for many years.

  However, in recent years, in addition to antennas that receive these radio waves, high-frequency GPS (Global Positioning System) antennas, or satellite radio waves for satellite digital broadcasting and their re-radiated waves (gap filler) An antenna that receives a radio wave) and an antenna that transmits and receives radio waves for a telephone such as a car phone or a cellular phone are becoming necessary for vehicles. Furthermore, as part of ITS (Intelligent Transport System), ETC (Automatic Tollgate System) that automatically collects tolls for highways and toll roads, and VICS (Road Traffic Information Communication System) that provides road traffic information Antennas that transmit and receive radio waves are also required for radio wave beacons. Therefore, recent vehicles have to be equipped with antennas for receiving or transmitting many types of radio waves (media).

  In general, a monopole antenna is often used as an antenna for receiving a broadcast wave among radio waves to be transmitted or received by such a mobile body. When the moving body is an automobile, the monopole antenna is often provided at the corner of the roof or the bumper. Recently, there is a monopole antenna that is embedded in the rear window or side window.

  However, when a monopole antenna is used for receiving a broadcast wave, the monopole antenna generally has a narrow reception band, so that there is a possibility that it cannot be handled when the frequency band of the broadcast wave is widened. In addition, the monopole antenna has a problem that its directivity is difficult to realize omnidirectionality. Further, the monopole antenna has a problem in that it is necessary to connect a ground to the body of the automobile near the antenna feeding point.

  Therefore, the present invention provides an omnidirectional antenna suitable for receiving broadcast waves, having directivity close to omnidirectional in a horizontal plane, having a wide band and excellent workability in mounting on an automobile. It is an object.

  The loop antenna of the present invention that achieves the above object can take the following 12 forms.

  According to a first aspect, an omnidirectional antenna is characterized in that a loop element is provided in a portion made of a dielectric of a vehicle, and a feeding point of the loop element is installed in a portion close to a conductor constituting the vehicle. It is.

  The second form is the omnidirectional antenna of the first form, wherein a parasitic element composed of a conductor independent of a conductor constituting the loop-shaped element is arranged in the vicinity of the loop-shaped element. It is a featured omnidirectional antenna.

  A third form is the omnidirectional antenna of the second form, wherein the parasitic element is formed of a first component parallel to a straight line connecting a substantial counter electrode of the loop-like element as viewed from the feeding point. The non-directional antenna is characterized in that the parasitic element is arranged such that the parasitic element has the first component when viewed as being decomposed into the vertical second component.

  The fourth embodiment is an omnidirectional antenna according to the second or third embodiment, wherein a part or all of the parasitic elements are arranged substantially parallel to the loop-shaped element. is there.

  The fifth embodiment is the omnidirectional antenna according to any one of the second to fifth embodiments, in which the parasitic element is placed on one side of a straight line that passes through the feeding point and bisects the loop-shaped element. It is an omnidirectional antenna characterized by having arranged only.

  The sixth embodiment is the omnidirectional antenna according to any one of the first to fifth embodiments, wherein the length of the conductor constituting the loop-shaped element is set to one wavelength of the frequency of the radio wave received by the omnidirectional antenna. An omnidirectional antenna is characterized by the following configuration.

  The seventh aspect is the omnidirectional antenna according to any one of the second to sixth aspects, wherein the length of the conductor constituting the parasitic element is set to half of the frequency of the radio wave received by the omnidirectional antenna. It is an omnidirectional antenna characterized by having a length corresponding to one wavelength or a length close to it.

  The eighth aspect is the omnidirectional antenna according to the first to seventh aspects, wherein one end of the conductor constituting the loop-shaped element is placed on the hot side of the coaxial cable or the power feeding circuit at the feeding point of the loop-shaped element. The omnidirectional antenna is characterized in that the other end is connected to the ground side of the coaxial cable or the power feeding circuit.

  The ninth embodiment is the omnidirectional antenna according to any one of the first to eighth embodiments, and the other end of the conductor constituting the loop element, the coaxial cable, and the power feeding circuit are all fed by the loop element. The omnidirectional antenna is characterized in that it is electrically insulated from the vehicle body in the vicinity of the part.

  A tenth aspect is an omnidirectional antenna according to any one of the first to ninth aspects, wherein a conductor constituting the vehicle is a pillar of the vehicle.

  The eleventh aspect is the omnidirectional antenna according to the tenth or eleventh aspect, wherein a plurality of loop-shaped elements are installed along the conductor.

The twelfth form is the omnidirectional antenna of the eleventh form, wherein the loop-shaped element is provided with a plurality of antennas in the vicinity of one end of the upper ends of the glass portion of the vehicle, and the other end. This is an omnidirectional antenna characterized in that a plurality of loop-shaped elements are provided in the vicinity of the part.
The thirteenth embodiment is the omnidirectional antenna of the eleventh or twelfth embodiment, and at least two of the plurality of antennas installed at one end portion are approximately the metal of the roof portion of the vehicle. It is an omnidirectional antenna characterized by being arranged at an equal distance.

  The fourteenth form is the omnidirectional antenna of the eleventh or twelfth form, and the first antenna installed at the top of the plurality of loop antennas arranged along the pillar is the first This is an omnidirectional antenna characterized by being horizontally long with respect to the second antenna disposed adjacent to the lower portion of the antenna.

  A fifteenth aspect is an omnidirectional antenna according to any one of the eleventh to fourteenth aspects, in which the phase and reception voltage of each signal received by some or all of the plurality of antennas are changed. The omnidirectional antenna is characterized in that it is synthesized so as to obtain desired directivity as an array antenna.

  A sixteenth aspect is an omnidirectional antenna according to any one of the eleventh to fourteenth aspects, in which a plurality of antennas are divided into a plurality of antenna groups, and a part of the plurality of antennas is divided in each antenna group. Alternatively, the phase and reception voltage of each signal received by all antennas are changed and combined, and as a result, the phase and reception voltage of some or all of the plurality of reception signals for each antenna group are changed. This is an omnidirectional antenna characterized by being synthesized.

  A seventeenth aspect is the omnidirectional antenna according to the sixteenth aspect, wherein a method of synthesizing signals from an antenna group is performed by changing the phase and the received signal voltage for each carrier existing in the reception band. It is an omnidirectional antenna characterized by combining signals from a group of antennas.

  The eighteenth aspect is the omnidirectional antenna according to any one of the eleventh to fifteenth aspects, wherein a plurality of carriers are provided by changing the phase and the received signal voltage for each carrier present in each of the signals received by the plurality of antennas. This is an omnidirectional antenna characterized by combining signals from the antennas.

  A nineteenth aspect is an omnidirectional antenna according to any one of the first to eighteenth aspects, wherein a conductor constituting the antenna is disposed on a transparent resin sheet. It is.

  As described above, according to the omnidirectional antenna of the present invention, the directivity is close to omnidirectional in a horizontal plane, and is excellent in workability in mounting on a vehicle such as an automobile with a wide band. An omnidirectional antenna suitable for reception can be provided. In particular, the omnidirectional antenna of the present invention has an effect that a high gain, omnidirectional antenna can be realized when installed in a dielectric part of a vehicle.

  Embodiments of an omnidirectional antenna according to the present invention will be described below in detail with reference to the accompanying drawings.

  FIG. 1A shows an example of an installation position when the omnidirectional antenna 10 of the present invention is attached to the front window 2 of the automobile 1. The positions where the omnidirectional antenna 10 of the present invention can be installed are, for example, positions L1 and L2 on the front window 2 near the left pillar (A pillar) 3L of the automobile 1 and the right pillar (A pillar) of the automobile 1 Positions R1 and R2 on the front window 2 near 3R, or positions F1 and F2 on the right side on the front window 2 near the roof 4 of the vehicle 1 (not shown, but may be on the left side).

  The distance from the roof 4 to the center of the position L1 is about 200 mm because there is an inspection chapter at the position indicated by a circle, the distance to the center of the position L2 is about 370 mm, and the pillar on the left side of the automobile 1 to the positions L1 and L2 The distance from 3L can be about 20 mm. The distance from the roof 4 to the center of the position R1 can be about 100 mm because there is no inspection chapter, and the distance to the center of the position L2 can be about 270 mm. Further, the distance from the right pillar 3R to the center of the position F1 may be about 100 mm.

  When the omnidirectional antenna 10 is installed in the front window 2 near the left pillar 3L of the automobile 1, it can be arranged side by side as positions L1 and L2 below the inspection chapter. Further, when the omnidirectional antenna 10 is installed in the front window 2 near the pillar 3R on the right side of the automobile 1, it can be arranged side by side as in the positions R1 and R2. Furthermore, when the omnidirectional antenna 10 is installed in the front window 2 near the roof 4 of the automobile 1, it can be arranged side by side as positions F1 and F2.

  When two omnidirectional antennas 10 are installed on the front window 2, two may be installed side by side at the same position as positions R1 and R2, but at different positions such as positions F1 and R1. Also good. Similarly, when three omnidirectional antennas 10 are installed on the front window 2, two positions at the same position and one position at different positions, such as positions R 1, R 2 and position F 1, or all at different positions. One by one can be installed. That is, when a plurality of omnidirectional antennas 10 are installed on the front window 2, these installation positions may be combined in any way.

  FIG. 1B shows a configuration of an embodiment of the omnidirectional antenna 10 installed in the vicinity of the left pillar 3L of the front window 2 shown in FIG. The omnidirectional antenna 10 of this embodiment is provided with a rectangular loop element 10A, and its power supply terminals 11 and 12 are installed on the left pillar 3L, that is, on the side close to the conductor constituting the automobile. Yes. A connector described later is connected to the power supply terminals 11 and 12. The shape of the loop element 10A is not limited to a rectangular shape, and may be an elliptical shape or a circular shape.

  FIG.1 (c) shows the structure of another Example of the omnidirectional antenna 10 installed in the vicinity of the left pillar 3L of the front window 2 shown to (a). The omnidirectional antenna 10 of this embodiment includes a loop-like element 10A similar to that shown in (b), and is a conductor independent of the loop-like element 10A in the vicinity of an adjacent side of the loop-like element 10A. The parasitic element 10 </ b> B configured by is arranged. By disposing the parasitic element 10B in the vicinity of the loop-shaped element 10A, the omnidirectional antenna 10 of this embodiment can obtain further excellent omnidirectional directivity.

  FIG. 1D shows a configuration of an embodiment of the omnidirectional antenna 10 installed in the vicinity of the right pillar 3R of the front window 2 shown in FIG. The omnidirectional antenna 10 of this embodiment is provided with a rectangular loop element 10A, and its power supply terminals 11 and 12 are installed on the right pillar 3R, that is, on the side close to the conductor constituting the automobile. Yes. A connector described later is connected to the power supply terminals 11 and 12. The omnidirectional antenna 10 of this embodiment can obtain further excellent omnidirectional directivity by disposing the parasitic element 10B at the position indicated by the two-dot chain line.

  FIG. 1E shows the configuration of an embodiment of an omnidirectional antenna 10 installed near the roof 4 of the front window 2 shown in FIG. The omnidirectional antenna 10 of this embodiment includes a rectangular loop-shaped element 10A, and its power supply terminals 11 and 12 are installed on the side close to the roof 4, that is, the conductor constituting the automobile. A connector described later is connected to the power supply terminals 11 and 12. The omnidirectional antenna 10 of this embodiment can obtain further excellent omnidirectional directivity by disposing the parasitic element 10B at the position indicated by the two-dot chain line.

  FIG. 1 (f) shows the configuration of another embodiment of the omnidirectional antenna 10 installed in the vicinity of the roof 4 of the front window 2 shown in (a), and the omnidirectional antenna described in (e). 10 variations. In the embodiment described in (e), the power supply terminals 11 and 12 are installed on the side close to the roof 4, but the power supply terminals 11 and 12 of this embodiment are installed on the side close to the pillar 3R. In any case, the power supply terminals 11 and 12 are installed on the side close to the conductor constituting the automobile.

  FIG. 2A shows an embodiment of the shape of the omnidirectional antenna 10 that is actually installed on the front window 2 of the automobile shown in FIG. The loop-shaped element 10A of this embodiment has a rectangular shape with a lateral width W of about 150 mm and a vertical width H of about 40 mm, and the power supply terminals 11 and 12 are inside the loop-shaped element 10A. , 6 mm square plate. Further, the line width of the loop-shaped element 10A can be about 0.3 mm. A broken line written around the power supply terminals 11 and 12 is a connector mounting position described later.

  FIG. 2B shows an embodiment in which a parasitic element 10B is disposed in the vicinity of the omnidirectional antenna 10 shown in FIG. 2A, and FIG. 2C shows the parasitic element 10B shown in FIG. The Example of another shape bent in the middle is shown. The parasitic element 10B of (c) is bent in parallel to the long side of the loop-shaped element 10A.

  The parasitic element 10B shown in FIG. 2B is perpendicular to the first component parallel to the straight line connecting the substantial counter electrode of the loop element 10A viewed from the power supply terminals 11 and 12 of the loop element 10A. When disassembled into the second component, the first component is arranged in the vicinity of the loop-shaped element 10A so that the first component exists. Since the loop-shaped element 10A of this embodiment is rectangular, the straight line connecting the substantial counter electrode of the loop-shaped element 10A viewed from the power supply terminals 11 and 12 of the loop-shaped element 10A is the center line of the loop-shaped element 10A. In other words, the parasitic element 10B only needs to have a component parallel to the vertical side (short side).

  Further, the parasitic element 10B shown in FIG. 2C includes a first component parallel to a straight line connecting a substantial counter electrode of the loop element 10A viewed from the power supply terminals 11 and 12 of the loop element 10A. When disassembled into the vertical second component, the first component and the second component are both present in the vicinity of the loop-shaped element 10A so that both are present. That is, the parasitic element 10B of this embodiment has a component parallel to the vertical side (short side) and the horizontal side (long side). As described above, the parasitic element 10B can be partially or entirely arranged in parallel with the loop element 10A. The parasitic element 10B does not need to be exactly parallel to each side of the loop element 10A, and there is no problem even if there is a slight deviation.

  In addition, the parasitic element 10B used in the omnidirectional antenna 10 of the present invention passes between the feeding terminals 11 and 12 of the loop-shaped element 10A, and the loop-shaped element viewed from the feeding terminals 11 and 12 of the loop-shaped element 10A. What is necessary is just to arrange | position only in any one side with respect to the straight line (centerline) which ties the substantial counter electrode of 10A. The length of the conductor constituting the loop-shaped element 10A is set to a length corresponding to approximately one wavelength of the frequency of the radio wave received by the omnidirectional antenna 10 or less. In addition, 1 wavelength is the length after the waveform shortening by the omnidirectional antenna 10 being installed in a dielectric material here. Furthermore, the length of the conductor constituting the parasitic element 10B is set to a length corresponding to one-half wavelength of the frequency of the radio wave received by the omnidirectional antenna 10 or a length close thereto.

  FIG. 3B is a characteristic diagram showing the horizontal directivity of the antenna when the omnidirectional antenna 10 is installed on the left pillar of the front window 2 of the automobile 1 shown in FIG. FIG. 3D is a characteristic diagram showing the horizontal directivity of the antenna when the omnidirectional antenna 10 is installed near the roof of the front window 2 of the automobile 1 shown in FIG. As can be seen from FIGS. 3 (b) and 3 (d), the omnidirectional antenna 10 of the present invention can provide a directivity closer to the omnidirectionality when installed along the pillar of the front window 2 of the automobile 1. . In addition, when the omnidirectional antenna 10 of the present invention is installed along the roof of the front window 2 of the automobile 1, it has omnidirectional characteristics, but has a characteristic having a slightly strong directivity in front of the antenna.

  FIG. 4 (a) is a characteristic diagram showing frequency characteristics of one-round average gain when the omnidirectional antenna 10 of the present invention is attached to a vehicle and the vehicle is rotated once horizontally, and FIG. It is a characteristic view which shows the frequency characteristic of 1 round average gain when a dipole antenna for comparison is attached to a vehicle and the vehicle is rotated once horizontally. The characteristic indicated by the solid line is when the antenna wiring is slightly lifted from the body, and the characteristic indicated by the broken line is when the antenna wiring is in close contact with the body. It can be seen that the omnidirectional antenna 10 of the present invention has no fluctuation in gain in all reception bands, whereas the folded dipole antenna has uneven gain with respect to the reception frequency in the reception band.

  FIG. 5A shows the appearance of the connector 20 connected to the omnidirectional antenna of the present invention. There are two openings 23 on the bottom surface (mounting surface to the antenna) 24 of the housing 21 of the connector 20, and connecting terminals 31 and 32 having spring properties protrude from the openings 23. The connection terminals 31 and 32 are attached to a circuit board (dielectric substrate) 30 built in the casing 21, and the coaxial cable 22 is connected to the circuit board 30. The bottom surface 24 of the connector 20 is attached to a position indicated by a broken line in FIGS. 2A to 2C with an adhesive such as a double-sided tape. In this embodiment, the connection terminal 31 is a hot side (signal transmission side) terminal, and the connection terminal 32 is a ground side terminal.

  FIG. 5B shows the configuration of the circuit board 30 inside the connector 20 shown in FIG. The connection terminals 31 and 32 are attached to the back side of the circuit board 30, led to the front side of the circuit board 30 through the through holes 33 and 34, and connected to a circuit (integrated circuit) 40 attached to the front side of the circuit board 30. ing. The coaxial cable 22 has a central conductor 22 </ b> A connected to the circuit 40 and an outer conductor 22 </ b> B connected to a ground-side connection terminal 32 on the circuit board 30. Thus, all of the ground side terminal of the loop-shaped element 10A, the outer conductor 22B of the coaxial cable 22, and the power feeding circuit 40 are electrically connected to the vehicle body in the vicinity of the power feeding portion of the loop-shaped element 10A. Not done.

  FIG. 5C shows the internal configuration of the circuit 40 shown in FIG. Inside the circuit 40, there are a filter 41 connected to the omnidirectional antenna 10, an amplifier 42 for amplifying a signal output from the filter 41, and a filter 43 for determining a signal band output from the amplifier 42. It is connected to the central conductor of the coaxial cable 22 through a capacitor 44 that prevents the above. The coaxial cable 22 is a power superimposed cable, and the superimposed power voltage is supplied to the amplifier 42 through the coil 45.

  FIGS. 6, 7, 8 (a), 8 (b), and 9 (a) to 9 (c) are first to seventh embodiments of the configuration of the receiver using the omnidirectional antenna of the present invention. FIG. In these figures, 10 is an omnidirectional antenna of the present invention, 51 is a tuner, 53 is an A / D converter, 54 is a fast Fourier demodulator, 55 is an adaptive synthesizer, 56 is band division combining diversity, and 57 is an error. A corrector, 58 is a decoder, 59 is selection diversity, and 60 is a television receiver.

  The omnidirectional antenna 10 of the present invention uses a plurality of the omnidirectional antennas 10 to change the phase and reception voltage of each signal received by some or all of the plurality of omnidirectional antennas 10, The array antenna can be synthesized so as to obtain desired directivity. Further, the plurality of omnidirectional antennas 10 described above are divided into a plurality of antenna groups, and in each antenna group, the phase and reception voltage of each signal received by some or all of the plurality of antennas are changed. Can be synthesized by changing the phase and the reception voltage of a part or all of the plurality of reception signals for each antenna group output as a result. Here, the configuration of the first to seventh embodiments of the receiver using the omnidirectional antenna 10 of the present invention will be briefly described.

  In the first embodiment shown in FIG. 6, four omnidirectional antennas 10 are used, and each antenna 10 is connected to a tuner 51. Analog signals received by the antenna 10, demodulated by the tuner 51, and output are converted into digital signals by the A / D converter 52, respectively. The digitally converted signal is input to the adaptive synthesizer 53 for each of the two antennas 10 and is synthesized by optimally matching the signal level (voltage) and phase. The synthesized signal is demodulated by the fast Fourier demodulator 54 and synthesized again by the adaptive synthesizer 55 to become one signal, which is input to the television receiver 60 through the error corrector 57 and the decoder 58.

  The four antennas 10 in the first embodiment receive the same radio wave, and their arrangement may be any of the four antenna positions L1, L2, F1, F2, R1, and R2 shown in FIG. However, it is preferable to prioritize two adjacent antenna positions and adaptively combine radio waves received at the two adjacent positions.

  Also in the second embodiment shown in FIG. 7, four omnidirectional antennas 10 are used, and each antenna 10 is connected to a tuner 51. The second embodiment is different from the first embodiment only in that the two signals demodulated by the fast Fourier demodulator 54 are input to the band division combining diversity 56 instead of the adaptive combining 53. . The band division combining diversity 56 does not synthesize two input signals like the adaptive synthesizer 53, but compares the subdivided bands in each signal for the two input signals for each band. One band is selected and combined. In the case of digital broadcasting, the band of one channel is very wide, and thousands of carriers are included in one band. Band division combining diversity 56 selects a better carrier for each of these thousands of carriers, combines the selected carriers, returns them to one band, and outputs them.

  Therefore, in the case of the second embodiment, it is better that the signals input to one band division combining diversity 56 are different, and it is better that the antenna positions are separated rather than adjacent. . For example, among the six antenna positions L 1, L 2, F 1, F 2, R 1, R 2 shown in FIG. 1, the antenna 10 at the position L 1 and the position L 2 on the left side of the front window 2 is connected to one adaptive combiner 53. , And the antenna 10 at the right positions R1 and R2 is connected to one adaptive combiner 53, the band division combining diversity 56 is connected to the signal received at the left position of the front window 2 and the right position. Since the better signal among the signals received in (1) is selected for each band, the reception performance is improved.

  In the third embodiment shown in FIG. 8A, the voltage and phase of a signal received by four omnidirectional antennas 10, demodulated by a tuner 51, and then converted into a digital signal by an A / D converter. Are different from the above-described two embodiments only in that they are optimally matched and synthesized by the adaptive synthesizer 53 and then demodulated by the fast Fourier demodulator 54. Since all the radio waves received by the four antennas 10 in the third embodiment are combined by the adaptive combiner 53, the positions of the four antennas are the positions L1, L2, F1 of the six antennas shown in FIG. , F2, R1, and R2 may be provided.

  In the fourth embodiment shown in FIG. 8B, the signals are received by the four omnidirectional antennas 10, demodulated by the tuner 51, converted into a digital signal by the A / D converter, and the fast Fourier demodulator 54. The signal demodulated in (1) differs from the other embodiments in that the signal is synthesized by selecting one out of four for each band by the band-division combining diversity 56.

  The fifth embodiment shown in FIG. 9A shows the configuration of the embodiment in which the antenna 10 of the receiver described in FIG. 8B is reduced from four to two. The sixth embodiment shown in b) shows a configuration of the embodiment in which the number of antennas 10 of the receiver described in FIG. 8A is reduced from four to two. If the number of antennas is changed from four to two, the circuit configuration is simplified.

  The seventh embodiment shown in FIG. 9C shows the configuration of a diversity antenna connected to the television receiver 60 that receives digital broadcasts. In this configuration, since the received signal is selected for each channel without dividing the band, the circuit configuration is simple. The omnidirectional antenna 10 of the present invention can also be used for a receiver having such a configuration.

  In the omnidirectional antenna 10 of the present invention, the conductors constituting the loop element 10A and the parasitic element 10B can be arranged on a transparent resin sheet.

(A) is explanatory drawing which shows the installation position to the front window of the motor vehicle of the omnidirectional antenna of this invention, (b) is one of the omnidirectional antennas installed in the vicinity of the left pillar of the front window shown in (a). The figure which shows the structure of an Example, (c) is a figure which shows the structure of another Example of the omnidirectional antenna installed in the left pillar vicinity of the front window shown to (a), (d) is a figure (a). The figure which shows the structure of one Example of the omnidirectional antenna installed near the pillar of the right side of the front window to show, (e) is one Example of the omnidirectional antenna installed in the roof vicinity of the front window shown to (a). (F) is a figure which shows the structure of one Example of the omnidirectional antenna installed in the vicinity of the roof of the front window shown in (a) and the connection part of the right pillar. (A) is a top view which shows one Example of the shape of the omnidirectional antenna actually installed in the front window of the motor vehicle shown to Fig.1 (a), (b) is the omnidirectionality shown to (a). FIG. 5C is a plan view showing an embodiment in which a parasitic element is disposed in the vicinity of the antenna, and FIG. 5C is a plan view showing an embodiment of another shape of the parasitic element shown in FIG. (A), (b) is a characteristic diagram showing the horizontal directivity of the antenna when an omnidirectional antenna is installed on the left pillar of the front window of the car, and (c), (d) are roofs of the front window of the car It is a characteristic view which shows the horizontal directivity of an antenna at the time of installing an omnidirectional antenna in the vicinity. (A) is a characteristic diagram showing a frequency characteristic of one-round average gain when the loop antenna is attached to the vehicle and the vehicle is rotated once horizontally, and (b) is a graph showing the frequency characteristic of the turn-around dipole antenna attached to the vehicle. It is a characteristic view which shows the frequency characteristic of the 1 round average gain when it rotates. (A) is a perspective view which shows the external appearance of the connector connected to the omnidirectional antenna of this invention, (b) is a top view which shows the structure of the circuit board in the inside of the connector shown to (a), (c) is It is a block circuit diagram which shows the internal structure of the circuit shown to (b). It is a block circuit diagram showing the 1st example of composition of a receiver using an omnidirectional antenna of the present invention. It is a block circuit diagram which shows the 2nd Example of a structure of the receiver which uses the omnidirectional antenna of this invention. (A) is a block circuit diagram showing a third embodiment of the configuration of the receiver using the omnidirectional antenna of the present invention, (b) is a block diagram of the configuration of the receiver using the omnidirectional antenna of the present invention. FIG. 6 is a block circuit diagram showing a fourth embodiment. (A) is a block circuit diagram showing a fifth embodiment of the configuration of the receiver using the omnidirectional antenna of the present invention, (b) is a block diagram of the configuration of the receiver using the omnidirectional antenna of the present invention. 6 is a block circuit diagram showing a sixth embodiment of the configuration of a receiver using the omnidirectional antenna of the present invention. FIG.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Car 2 Front window 3L Left pillar 3R Right pillar 4 Roof 10 Non-directional antenna 10A Loop element 10B Parasitic element 20 Connector 22 Coaxial cable 30 Dielectric substrate (circuit board)
31, 32 Connection terminal 33, 34 Through hole 40 Circuit

Claims (19)

  An omnidirectional antenna characterized in that a loop element is provided in a part made of a dielectric of a vehicle, and a feeding point of the loop element is installed in a part close to a conductor constituting the vehicle. The omnidirectional antenna according to claim 1,
A non-directional antenna comprising a parasitic element made of a conductor independent of a conductor constituting the loop element, in the vicinity of the loop element. The omnidirectional antenna according to claim 2,
When the parasitic element is viewed as being decomposed into a first component parallel to a straight line connecting a substantial counter electrode of the loop-like element viewed from the feeding point and a second component perpendicular thereto, An omnidirectional antenna, wherein the parasitic element is arranged such that the first component is present in the parasitic element. The omnidirectional antenna according to claim 2 or 3,
An omnidirectional antenna, wherein a part or all of the parasitic element is disposed substantially parallel to the loop element. The omnidirectional antenna according to any one of claims 2 to 4,
An omnidirectional antenna, wherein the parasitic element is disposed only on one side of a straight line that bisects the loop-shaped element through the feeding point. An omnidirectional antenna according to any one of claims 1 to 5,
An omnidirectional antenna, wherein a length of a conductor constituting the loop-shaped element is configured to be one wavelength or less of a frequency of a radio wave received by the omnidirectional antenna. The omnidirectional antenna according to any one of claims 2 to 6,
The non-directional characteristic characterized in that the length of the conductor constituting the parasitic element is set to a length corresponding to a half wavelength of the frequency of the radio wave received by the non-directional antenna or a length close thereto. Sex antenna. The omnidirectional antenna according to any one of claims 1 to 7,
At the feeding point of the loop element, one end of the conductor constituting the loop element is connected to the hot side of the coaxial cable or the feeding circuit, and the other end is connected to the ground side of the coaxial cable or the feeding circuit. A characteristic omnidirectional antenna. The omnidirectional antenna according to any one of claims 1 to 8,
The other end of the conductor constituting the loop-shaped element, the coaxial cable, and the power feeding circuit are all electrically insulated from the vehicle body in the vicinity of the power feeding portion of the loop-shaped element. Omnidirectional antenna. The omnidirectional antenna according to any one of claims 1 to 9,
An omnidirectional antenna characterized in that a conductor constituting the vehicle is a pillar of the vehicle. The omnidirectional antenna according to claim 10,
An omnidirectional antenna comprising a plurality of loop-shaped elements installed along the conductor. The omnidirectional antenna according to claim 11,
The loop element is provided with a plurality of antennas in the vicinity of one end of the upper end portions of the glass portion of the vehicle, and a plurality of loop elements in the vicinity of the other end. Directional antenna. The omnidirectional antenna according to claim 11 or 12,
An omnidirectional antenna, wherein at least two antennas among a plurality of antennas installed at one end portion are arranged at a substantially equal distance from a metal of a roof portion of a vehicle. The omnidirectional antenna according to claim 11 or 12,
Of the plurality of loop antennas arranged along the pillar, the first antenna installed at the top is horizontally long with respect to the second antenna arranged adjacent to the lower part of the first antenna. An omnidirectional antenna characterized by being. The omnidirectional antenna according to any one of claims 11 to 14,
Non-directivity characterized in that a desired directivity is obtained as an array antenna by changing the phase and reception voltage of each signal received by some or all of the plurality of antennas. antenna. The omnidirectional antenna according to any one of claims 11 to 14,
The plurality of antennas are divided into a plurality of antenna groups, and in each antenna group, the phases and reception voltages of the signals received by some or all of the plurality of antennas are changed and combined, and the result The omnidirectional antenna is characterized in that it is synthesized by changing the phase and reception voltage of a part or all of a plurality of reception signals for each antenna group output as. The omnidirectional antenna according to claim 16,
A method for synthesizing signals from the antenna group is characterized by synthesizing signals from a plurality of antenna groups by changing a phase and a received signal voltage for each of a plurality of carriers in a reception band. . The omnidirectional antenna according to any one of claims 11 to 15,
An omnidirectional antenna characterized by combining signals from a plurality of antennas by changing a phase and a received signal voltage for each of a plurality of carriers received in each of the signals received by the plurality of antennas. The omnidirectional antenna according to any one of claims 1 to 18,
An omnidirectional antenna, wherein a conductor constituting the antenna is disposed on a transparent resin sheet.

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