Patent Description:
Patent Literature <NUM> discloses an antenna device mounted on a vehicle. In the antenna device, a conductor plate electrically connected to a metal base is brought into contact with a vehicle body roof, which is an example of a base plate. According to this configuration, unnecessary resonance caused by the metal base having a resonance point corresponding to a distance to the vehicle body roof is prevented from occurring in a required frequency band.

Patent Literature <NUM> discloses an electromagnetic interference suppressing body used for suppressing electromagnetic interference caused by interference of unnecessary electromagnetic waves in an electronic device, and an electromagnetic interference suppressing method using the same.

Patent Literature <NUM> discloses an antenna unit having an antenna device mounted on a substrate made of a conductive material and particularly to an antenna unit, which has less distortion in its directivity due to secondary radio wave signals radiated from the substrate.

Patent Literature <NUM> discloses a beam shaping device for an outdoor and/or roof antenna on motor vehicles having, on an electrically non-conductive area of a vehicle body, in particular in the form of a glass pane, is an antenna mounting area or section.

In the antenna device described in Patent Literature <NUM>, although the unnecessary resonance is shifted out of the required frequency band, the occurrence of unnecessary resonance itself cannot be reduced.

An object of the present disclosure is to provide an antenna device capable of reducing occurrence of unnecessary resonance.

According to an aspect of the present invention for achieving the above object, there is provided an antenna device configured to be mounted on a base plate according to claim <NUM>.

The magnetic body may be configured to be disposed between a glass and the base, the glass covering at least a part of the base plate and the base.

A thickness of the magnetic body in an upward-downward direction may be <NUM> or more, and an imaginary part of a magnetic permeability of the magnetic body may be <NUM> or more.

The thickness of the magnetic body in the upward-downward direction may be <NUM> or more, and the imaginary part of the magnetic permeability of the magnetic body may be <NUM> or more.

Hereinafter, embodiments will be described in detail with reference to the drawings. The same or equivalent components, members, or the like illustrated in the drawings are denoted by the same reference numerals, and a repetitive description thereof will be omitted.

In the accompanying drawings, an arrow F indicates a forward direction of the illustrated structure. An arrow B indicates a backward direction of the illustrated structure. An arrow U indicates an upward direction of the illustrated structure. An arrow D indicates a downward direction of the illustrated structure. These expressions relating to these directions are merely used for convenience of description, and are not intended to limit a posture of an antenna device when the antenna device is used.

<FIG> is a sectional view schematically showing an antenna device <NUM> according to a first embodiment. The antenna device <NUM> is configured to be mounted on a vehicle. Specifically, the antenna device <NUM> is configured to be mounted on a base plate <NUM> such as a vehicle body roof.

The antenna device <NUM> includes an antenna element <NUM>, a base <NUM>, a power supply cylindrical portion <NUM>, and a magnetic body <NUM>. In <FIG>, illustrations of a substrate and an electronic component or the like disposed on an exterior case or the base <NUM> are omitted.

In the example, the antenna element <NUM> is a TEL antenna. The antenna element <NUM> is mounted on the base <NUM> made of metal.

The power supply cylindrical portion <NUM> extends downward from the base <NUM>. The power supply cylindrical portion <NUM> is electrically connected to the base plate <NUM> on a vehicle body side. The power supply cylindrical portion <NUM> is a metal component integral with the base <NUM>. The power supply cylindrical portion <NUM> may be a separate metal component electrically connected to the base <NUM>, which is not part of the claimed invention.

The magnetic body <NUM> is a magnetic body sheet. The magnetic body <NUM> is provided on a lower surface of the base <NUM>. The magnetic body <NUM> is fixed to the lower surface of the base <NUM> by adhesion or the like. The magnetic body <NUM> is disposed so as to be interposed between the base <NUM> and the base plate <NUM>. The magnetic body <NUM> may be provided on the entire lower surface of the base <NUM>, or may be provided on a part of the lower surface. In a case where the magnetic body <NUM> is provided on a part of the lower surface of the base <NUM>, it is preferable that the magnetic body <NUM> be disposed at least around the power supply cylindrical portion <NUM>. From a viewpoint of dimensional accuracy, occurrence of a gap between the base <NUM> and the base plate <NUM> cannot be avoided, and the magnetic body <NUM> is provided so as to fill the gap.

<FIG> is a frequency characteristic diagram of an average gain obtained by actual measurement, for explaining an effect of the magnetic body in the antenna device <NUM>. <FIG> shows characteristics of the antenna device <NUM> having the magnetic body <NUM> with a high imaginary part µ" of a magnetic permeability, the antenna device <NUM> having the magnetic body <NUM> with a low imaginary part µ" of the magnetic permeability, and an antenna device in a comparative example in which the magnetic body <NUM> is removed from the antenna device <NUM>.

<FIG> is a frequency characteristic diagram of a VSWR obtained by the actual measurement, for explaining the effect of the magnetic body in the antenna device <NUM>. <FIG> shows characteristics of the antenna device <NUM> having the magnetic body <NUM> with the high imaginary part µ" of the magnetic permeability, the antenna device <NUM> having the magnetic body <NUM> with the low imaginary part µ" of the magnetic permeability, and the antenna device in the comparative example in which the magnetic body <NUM> is removed from the antenna device <NUM>.

In the antenna device <NUM> shown in <FIG> and <FIG>, a magnetic body sheet having a thickness t of <NUM> in an upward-downward direction is used as the magnetic body <NUM>. A value of a real part µ' of the magnetic permeability of the magnetic body <NUM> is µ' = <NUM> in any of the antenna device <NUM>. The value of the imaginary part µ" of the magnetic permeability of the magnetic body <NUM> is one of µ" = <NUM> (µ" is high) and µ" = <NUM> (µ" is low). As shown in <FIG> and <FIG>, by providing the magnetic body <NUM>, the antenna device <NUM> can reduce unnecessary resonance from occurring as compared with the case where the magnetic body <NUM> is not provided, regardless of the value of the imaginary part µ" of the magnetic permeability of the magnetic body <NUM>.

<FIG> is a view schematically showing a configuration of the antenna device <NUM> used for a simulation shown in <FIG>. The base <NUM> whose lower surface is provided with the magnetic body <NUM> is disposed above the base plate <NUM> with a gap therebetween. A distance between the base <NUM> and the base plate <NUM> is <NUM>. The antenna element <NUM> is erected on the base <NUM>. The base <NUM> and the base plate <NUM> are electrically connected to each other by the power supply cylindrical portion <NUM>.

<FIG> is a frequency characteristic diagram of an average gain obtained by the simulation of the antenna device <NUM>, in a case where the value of the imaginary part µ" of the magnetic permeability of the magnetic body <NUM> is changed. In each case, a length L of the magnetic body <NUM> in the forward-backward direction is <NUM>. The thickness t of the magnetic body <NUM> is <NUM>. The value of the real part µ' of the magnetic permeability of the magnetic body <NUM> is µ' = <NUM>. The value of the imaginary part µ" of the magnetic permeability of the magnetic body <NUM> is shown in cases of µ" = <NUM>, µ" = <NUM>, and µ" = <NUM>.

As is apparent from <FIG>, in the case where the thickness t of the magnetic body <NUM> is <NUM>, there is no large difference in the average gain at any µ" except at the frequency of <NUM> to <NUM>. On the other hand, when the frequency is <NUM> to <NUM>, the average gain is greatly improved in the case of µ" = <NUM> than in the case of µ" = <NUM> or µ" = <NUM>. Therefore, in the case where the thickness t of the magnetic body <NUM> is <NUM>, it is preferable that the imaginary part µ" of the magnetic permeability be <NUM> or more. If the thickness t of the magnetic body <NUM> is larger than <NUM>, the unnecessary resonance is further reduced, and the average gain is further improved. Such an example will be described with reference to <FIG>.

<FIG> is a frequency characteristic diagram of the average gain obtained by the simulation of the antenna device <NUM>, in a case where the value of the imaginary part µ" of the magnetic permeability of the magnetic body <NUM> having the thickness t of <NUM> is changed. In each case, the length L of the magnetic body <NUM> in the forward-backward direction is <NUM>. The value of the real part µ' of the magnetic permeability of the magnetic body <NUM> is µ' = <NUM>. The value of the imaginary part µ" of the magnetic permeability of the magnetic body <NUM> is shown in the cases of µ" = <NUM>, µ" = <NUM>, and µ" = <NUM>.

As is apparent from <FIG>, in the case where the thickness t of the magnetic body <NUM> is <NUM>, there is no large difference in the average gain at any µ" except at the frequency of <NUM> to <NUM>. On the other hand, when the frequency is <NUM> to <NUM>, the average gain is greatly improved in the case of µ" = <NUM> or µ" = <NUM> than in the case of µ" = <NUM>. Therefore, in the case where the thickness t of the magnetic body <NUM> is <NUM>, the imaginary part µ" of the magnetic permeability is preferably <NUM> or more. If the thickness t of the magnetic body <NUM> is larger than <NUM>, the unnecessary resonance is further reduced, and the average gain is further improved. Such an example will be described with reference to <FIG>.

As is apparent from <FIG>, in the case where the thickness t of the magnetic body <NUM> is <NUM>, there is no large difference in the average gain at any µ" except at the frequency of <NUM> to <NUM>. On the other hand, when the frequency is <NUM> to <NUM>, the average gain is greatly improved in the case of µ" = <NUM> or µ" = <NUM> than in the case of µ" = <NUM>. Therefore, in the case where the thickness t of the magnetic body <NUM> is <NUM>, the imaginary part µ" of the magnetic permeability is preferably <NUM> or more. As a result, if the thickness t of the magnetic body <NUM> is larger than <NUM>, the unnecessary resonance is further reduced, and the average gain is further improved.

<FIG> is a frequency characteristic diagram of the average gain obtained by the simulation of the antenna device <NUM>, in a case where the length of the magnetic body <NUM> in the forward-backward direction is changed. In each case, the thickness t of the magnetic body <NUM> is <NUM>. The value of the real part µ' of the magnetic permeability of the magnetic body <NUM> is µ' = <NUM>. The value of the imaginary part µ" of the magnetic permeability of the magnetic body <NUM> is µ" = <NUM>. The length L of the magnetic body <NUM> in the forward-backward direction is shown for <NUM>, <NUM>, <NUM>, <NUM>, and <NUM>.

As is apparent from <FIG>, when the length L of the magnetic body <NUM> in the forward-backward direction becomes long, the frequency at which the average gain decreases becomes low. Therefore, in order to shift unnecessary resonance out of a required frequency band, it is effective to change the length L of the magnetic body <NUM> in the forward-backward direction.

<FIG> is a characteristic diagram showing a result, in the antenna device <NUM> according to <FIG>, of simulating a relationship between the imaginary part µ" of the magnetic permeability and a minimum value of the average gain in a range of the frequency of <NUM> to <NUM>. That is, the length L of the magnetic body <NUM> in the forward-backward direction is <NUM>. The thickness t of the magnetic body <NUM> is <NUM>. The value of the real part µ' of the magnetic permeability of the magnetic body <NUM> is µ' = <NUM>.

As is apparent from <FIG>, in a range where µ" is <NUM> or less, the minimum value of the average gain increases as µ" increases. On the other hand, in a range where µ" is <NUM> or more, the minimum value of the average gain tends to converge. In combination with the result of <FIG> showing the relationship between the average gain and the frequency under the same conditions, it has been found that a high minimum value of the average gain is obtained by setting the thickness t of the magnetic body <NUM> to <NUM> or more and the imaginary part µ" of the magnetic permeability to <NUM> or more.

<FIG> is a characteristic diagram showing a result, in the antenna device <NUM> according to <FIG>, of simulating a relationship between the imaginary part µ" of the magnetic permeability and the minimum value of the average gain in the range of the frequency of <NUM> to <NUM>. That is, the length L of the magnetic body <NUM> in the forward-backward direction is <NUM>. The thickness t of the magnetic body <NUM> is <NUM>. The value of the real part µ' of the magnetic permeability of the magnetic body <NUM> is µ' = <NUM>.

As is apparent from <FIG>, in a range where µ" is <NUM> or less, the minimum value of the average gain increases as µ" increases. On the other hand, when µ" is <NUM> or more, the minimum value of the average gain tends to converge. In combination with the result of <FIG> showing the relationship between the average gain and the frequency under the same conditions, it has been found that a high minimum value of the average gain is obtained by setting the thickness t of the magnetic body <NUM> to <NUM> or more and the imaginary part µ" of the magnetic permeability to <NUM> or more.

Also in the case where the thickness t of the magnetic body <NUM> is t = <NUM> as in the example shown in <FIG>, the relationship between the imaginary part µ" of the magnetic permeability and the minimum value of the average gain shows the same tendency.

As described above, the magnetic body <NUM> is disposed so as to be interposed between the base <NUM> and the base plate <NUM>, so that the unnecessary resonance can be reduced.

<FIG> is a sectional view schematically showing an antenna device 1A according to a second embodiment. The antenna device 1A differs from the configuration of first embodiment in that a glass <NUM> on the vehicle body side is interposed between the base <NUM> and the base plate <NUM>, and the magnetic body <NUM> is interposed between the base <NUM> and the glass <NUM>. The glass <NUM> covers at least a part of the base plate <NUM>. The magnetic body <NUM> is provided so as to fill a gap formed between the base <NUM> and the glass <NUM>. According to such a configuration, the same effect as that of the antenna device <NUM> according to the first embodiment can be obtained.

Claim 1:
An antenna device (<NUM>) configured to be mounted on a base plate (<NUM>), comprising:
an antenna element (<NUM>);
a base (<NUM>) made of metal and mounted thereon with the antenna element; and
a magnetic body (<NUM>) provided on a lower surface of the base (<NUM>) and configured to be disposed between the base (<NUM>) and the base plate (<NUM>);
a power supply cylindrical portion (<NUM>) extending downward from the base (<NUM>),
wherein the magnetic body (<NUM>) is disposed at least around the power supply cylindrical portion (<NUM>),
characterized in that the power supply cylindrical portion (<NUM>) is a metal component integral with the base (<NUM>).