JPH10270272A - Antenna equipment - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an antenna equipment of simple structure which can supply electric power from a fixed part side to a rotary part side in a non-contact manner. SOLUTION: A fixed side insulating plate 61 is arranged on a fixed part which is fixed on the bottom surface of a housing. A rotary side insulating plate 62 is arranged on a rotary part retained by the fixed part, so as to face the fixed side insulating plate 61. An antenna is arranged on the rotary part. A first inductor 63 is arranged on the fixed side insulating plate 61, and a second inductor 64 which is electromagnetically coupled with the first inductor 63 is arranged on the rotary side insulating plate 62. When an AC current is made to flow in the first inductor 63, an induced electromotive force is generated in the second inductor 64 which is caused by the change of magnetic flux generated in the first inductor 63, and electric power is supplied from the fixed part side to the rotary part side. Rotary couplers are arranged in the central part of the fixed side insulating plate 61 and the rotary side insulating plate 62.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an antenna device mounted on a moving body such as an automobile or a ship, and particularly for receiving a signal from a satellite.

[0002]

2. Description of the Related Art With the spread of satellite broadcasting in recent years, various types of antenna apparatuses for receiving satellite broadcasting which are mounted and used on mobile bodies have been proposed. In this type of antenna device,
Since the direction of the moving body changes every moment as it travels, an automatic tracking mechanism for controlling the azimuth of the antenna is required so that the antenna always faces the satellite. For this reason, the satellite broadcast RF (radio freq
uency) A rotary coupler that allows the antenna to rotate while maintaining electrical coupling in the signal frequency band is provided in the middle of the electric line connecting the converter and the tuner, which converts the signal to an IF (intermediate frequency) signal. ing. In addition, a slip ring for allowing rotation of the antenna is provided in the middle of a feed line for supplying power to the converter (Japanese Patent Laid-Open No. 7-94928).

FIG. 9 is a diagram for explaining a rotary coupler and a slip ring used in a conventional antenna device. The fixing portion 111 is fixed to a bottom surface of a storage body (not shown). The rotating part 112 is supported by the fixed part 111 and is configured to be rotatable around an axis C perpendicular to the bottom surface of the housing via a bearing 121. An antenna is mounted on the rotating unit 112. As the antenna, for example, a leaky-wave waveguide slot array antenna is used (Japanese Unexamined Patent Application Publication No.
188625). Further, a converter is provided, for example, on the back surface of the antenna.

[0004] The rotary coupler 130 includes a lower rotary coupler 13.
1 and an upper rotary coupler 132. The lower rotary coupler 131 is provided on the fixed part 111, while the upper rotary coupler 132 is provided on the rotating part 112 so as to face the lower rotary coupler 131. Upper rotary coupler 132
Is connected to the converter by a cable line, and the lower rotary coupler 131 is connected to the tuner by a cable line. Lower rotary coupler 131 and upper rotary coupler 13
2 forms a C-coupling, whereby the IF signal converted by the converter is transferred from the upper rotary coupler 132 to the lower rotary coupler 131.

[0005] The slip ring 140 is fixed to the fixed part 1.
The transmission ring 141 fixed to the
A transmission ring 142 fixed to the side and a plurality of brushes (armatures) 143 held between the transmission rings 141 and 142 so as to be slidable with respect to each other. Through the slip ring 140, operating power is supplied from the fixed part 111 to the converter on the rotating part 112 side.

[0006]

However, the above-mentioned slip ring is of a so-called contact type, and if used for a long time, the brush is made of metal and is worn. Therefore, there is a problem that sufficient power cannot be supplied to the converter due to wear of the brush. Moreover, the structure of the slip ring is complicated. On the other hand, it is conceivable to use a wire instead of the slip ring. However, when a wire is used, the rotating unit can be rotated only to a certain extent, and infinite rotation cannot be performed. That is, a wired type may be used if it is a fixed type, but a wired type cannot be used if it is a rotary type like an antenna device. Moreover,
In the case of wire, long-term use causes metal fatigue and may cause disconnection.

The present invention has been made based on the above circumstances, and an object of the present invention is to provide an antenna device which can supply electric power from a fixed portion to a rotating portion in a non-contact manner with a simple configuration. Things.

[0008]

SUMMARY OF THE INVENTION In order to achieve the above object, the present invention provides a fixing part and a rotating part supported by the fixing part so as to be rotatable about an axis perpendicular to the fixing part. And, in an antenna device including a rotation mechanism for rotating the rotating portion, a first insulating plate provided on the fixed portion,
A second insulating plate provided on the rotating portion so as to face the first insulating plate, a first inductor provided on the first insulating plate, and a first inductor provided on the second insulating plate; By providing an inductor and a second inductor that is electromagnetically coupled, when an alternating current flows through the first inductor, by generating an induced electromotive force in the second inductor by a change in magnetic flux generated in the first inductor, Power is supplied from the fixed part side to the rotating part side.

In the present invention, the first insulating plate provided on the fixed portion, the second insulating plate provided on the rotating portion so as to face the first insulating plate, and the first insulating plate provided on the first insulating plate. By providing an inductor and a second inductor provided on the second insulating plate and electromagnetically coupled to the first inductor, when an alternating current is applied to the first inductor, a magnetic flux is generated in the first inductor, and a change in the magnetic flux is generated. As a result, an induced electromotive force is generated in the second inductor. For this reason, electric power can be supplied from the fixed part side to the rotating part side in a non-contact manner, and the transferred voltage can be used for the power supply of the converter.

[0010]

DESCRIPTION OF THE PREFERRED EMBODIMENTS One embodiment of the present invention will be described below with reference to the drawings. FIG. 1 is a schematic block diagram of an antenna device according to an embodiment of the present invention, and FIG. 2 is a schematic configuration diagram when the antenna device is mounted on a vehicle.
The antenna device shown in FIG. 1 is mounted on a mobile object to receive satellite broadcasts, and includes an antenna 10, a converter 20, a rotary coupler 30, a tuner 40, an azimuth control device 50, It includes a power transfer unit 60 and a power supply device 70. The azimuth controller 50 controls the antenna 10 so that the antenna 10 always faces the direction of the broadcasting satellite (BS).
The azimuth angle is controlled by tracking a reception level detector 51, an gyro 52, a control unit 53, and a rotation mechanism unit 5.
And 4.

In the present embodiment, such an antenna device is
For example, consider the case of mounting on a car. In this case, as shown in FIG. 2, the antenna device is configured such that each unit is divided into an antenna unit 1 and a tuner unit 2. The antenna unit 1 is mounted on the roof of an automobile, and the tuner unit 2 is installed inside the automobile. The tuner unit 2 is connected to, for example, a television receiver A mounted on the front surface of the passenger seat.

The antenna unit 1 includes an antenna 10, a converter 20, a rotary coupler 30, a rotation mechanism 54, and a power transfer unit 60. Antenna 1
Numeral 0 receives a radio wave transmitted from a broadcasting satellite. In the present embodiment, a leaky waveguide slot array antenna is used. Such a leaky-wave waveguide slot array antenna has a tilt angle (beam peak direction) and a wide half-value angle in the elevation direction. Therefore, if the moving range of the moving body is not too wide, only the azimuth control is performed. There is an advantage that the radio wave from the broadcasting satellite can be reliably received. For this reason, in the antenna device of the present embodiment, only the control of the azimuth is performed.

The converter 20 converts a satellite broadcast RF (radio frequency) signal received by the antenna 10 into an IF (in
termediate frequency) signal. The converter 20 is attached to, for example, the back surface of the antenna 10. Converter 20 is supplied with power from power supply device 70 via power transfer unit 60. The IF signal converted by the converter 20 is sent to the tuner 40 via the rotary coupler 30. The rotary coupler 30 is connected to the converter 20.
The antenna is provided in the middle of a wire path connecting between the antenna 10 and the tuner 40 so as to enable the antenna 10 to rotate in the azimuth direction while maintaining electrical coupling in the signal frequency band.

The tuner unit 2 includes a tuner 40
, A reception level detector 51, an gyro 52, a control unit 53, and a power supply 70. The tuner 40
The IF signal converted by the converter 20 is demodulated into a video signal and an audio signal, and supplied to the television receiver A. The reception level detector 51 detects the antenna 10 based on the noise level output from the automatic gain control amplification in the tuner 40.
Detects the level of the received signal (reception level). The angular velocity meter 52 detects an angular velocity generated when the moving body changes the course or turns.

The control unit 53 controls the rotation direction and the rotation for controlling the azimuth of the antenna 10 based on the reception level detected by the reception level detector 51 and the signal related to the angular velocity sent from the gyro 52. Determine the angle.
A signal corresponding to the determined rotation direction and rotation angle is sent to the rotation mechanism 54, and the azimuth of the antenna 10 is controlled.

FIG. 3 is a schematic partial sectional view of the antenna unit 1 in the antenna device of the present embodiment. Here, the lower part of the antenna unit 1 is shown.
The fixing portion 81 is fixed on a base plate (not shown) which is a bottom plate of the antenna unit 1. Rotating part 82
Are supported on the fixing portion 81. A bearing 83 is provided between the fixed portion 81 and the rotating portion 82, and the rotating portion 8
2 is configured to be rotatable around an axis C perpendicular to the base plate by a bearing 83. The antenna 10 is mounted on the rotating part 82. Control unit 53
Sends a signal to the rotation mechanism 54 to drive a motor (not shown) of the rotation mechanism 54. The rotation of the motor is transmitted to the rotation unit 82, and the azimuth of the antenna 10 is controlled. The antenna unit 1 is covered with a radome (not shown) serving as a cover from above.

Next, the structure of the power transfer section 60 in the antenna device of the present embodiment will be described. FIG. 4 is a schematic cross-sectional view of a power transfer unit and a rotary coupler in the antenna device, and FIG. 5A is a diagram illustrating a shared portion provided in a rotary unit among two shared substrates of the power transfer unit and the rotary coupler shown in FIG. FIG. 5B is a schematic rear view of the shared substrate shown in FIG. 5A, and FIG. 6A is a schematic plan view of the two shared substrates of the power transfer unit and the rotary coupler shown in FIG. FIG. 6B is a schematic rear view of the shared substrate shown in FIG. 6A, and FIG. 7 is an equivalent circuit diagram of the power transfer unit shown in FIG. Although the substrates shown in FIGS. 4 to 6 have the same size, the present invention is not limited to this, and the upper substrate may be larger in consideration of mounting.

As shown in FIGS. 4 to 7, the power transfer unit 60 includes a fixed-side insulating plate 61, a rotating-side insulating plate 62, a first inductor 63, and a second inductor electromagnetically coupled to the first inductor 63. 64, a rectifier circuit 65, and a transfer voltage control means 66. Here, the load in FIG. 7 is a load that requires a power supply on the rotating section 82 side, specifically, the converter 20. As shown in FIG. 3, the fixed side insulating plate 61 is provided on the fixed portion 81, and the rotating side insulating plate 62 is
2 is provided. Further, the fixed-side insulating plate 61 and the rotating-side insulating plate 62 are arranged to face each other at a certain interval. For example, the distance between the fixed insulating plate 61 and the rotating insulating plate 62 is set to about 1 mm. Fixed insulating plate 61 and rotating insulating plate 62
Is used as a common substrate for the power transfer unit 60 and the rotary coupler 30.

The first inductor 63 is provided on the fixed insulating plate 61, and the second inductor 64 is provided on the rotating insulating plate 62. As the first inductor 63, a fixed spiral insulating plate 61 printed with a circular spiral pattern is used. Such a spiral pattern is formed on both surfaces of the fixed-side insulating plate 61 except for the central portion thereof so as to connect from the front surface to the back surface. Similarly, a second inductor 64 having a circular spiral pattern printed on the rotation-side insulating plate 62 is used. Such a spiral pattern is also formed on the rotation side insulating plate 62.
Are formed on both sides except for the central part of. The spiral pattern of the first inductor 63 and the spiral pattern of the second inductor 64 may have the same size, number of turns, and the like. Here, each spiral pattern is formed so as to be connected from the front surface to the back surface of the insulating plates 61 and 62, respectively, in order to increase the number of windings and to capture magnetic flux as efficiently as possible. Note that a rotary coupler 30 described later in detail is formed at the center between the fixed-side insulating plate 61 and the rotating-side insulating plate 62.

In the power transfer section 60, the electromagnetic coupling between the first inductor 63 and the second inductor 64 is used.
Power is supplied to the converter 20. That is, when an alternating current of, for example, 200 kHz to 300 kHz flows in the first inductor 63, a magnetic flux is generated in the first inductor 63. Then, an induced electromotive force is generated in the second inductor 64 by the change of the magnetic flux. The induced current due to the induced electromotive force is half-wave rectified by the rectifier circuit 65. Here, the rectifier circuit 65 has a diode 65a and a capacitor 65b as shown in FIG. Charge is stored in the capacitor 65b, and a voltage determined by the capacitance is output to the converter 20. Thus, electric power is supplied from the fixed part 81 to the rotating part 82. Note that, instead of half-wave rectification by the rectifier circuit 65, full-wave rectification may be performed.

In this embodiment, for example, when the input voltage is 24
V, and when a current of 160 mA flows (power is about 3.8 W), the first inductor 63 and the second inductor 64
The power transfer unit 60 is designed such that the output voltage taken out to the load side is 11.15 V and the current flows about 135 mA (the power is about 1.5 W) via the electromagnetic coupling with the power supply. At this time, the efficiency is 1.5 / 3.8 = 40%. Since this includes the power used for the circuit (such as the power supply of the IC), the actual efficiency is slightly better. Further, the above values are obtained when the distance between the fixed-side insulating plate 61 and the rotating-side insulating plate 62 is 1 mm, so that the distance between the fixed-side insulating plate 61 and the rotating-side insulating plate 62 is about 0.5 mm. If reduced, it is possible to realize an efficiency of about 50%.

Incidentally, mass-produced converters do not have exactly the same performance, and there is naturally a variation in load depending on the converter. The fixed-side insulating plate 61 and the rotating-side insulating plate 6
Naturally, the gap between the two also varies due to manufacturing errors and the like.
If there is such a variation, the voltage applied to the load on the rotating section 82 will change. Therefore, in the present embodiment, the transfer voltage control means 66 is provided. The transfer voltage control means 66 has a monitoring inductor 66a and a control unit 66b, as shown in FIGS. The monitoring inductor 66 a is provided on the fixed-side insulating plate 61 inside the first inductor 63. Monitoring inductor 66
As a, a printed circular pattern is used. Such a circular pattern is formed on both sides of the fixed-side insulating plate 61 except for the central portion thereof so as to connect from the front surface to the back surface. The monitoring inductor 66a monitors the strength of the electromagnetic coupling between the first inductor 63 and the second inductor 64 by detecting the induced electromotive force generated by itself. Then, the control unit 66b controls the monitoring inductor 66a.
Is controlled based on the induced electromotive force generated in the first inductor 63 so that the voltage transferred to the rotating unit 82 side becomes a predetermined value. As a control method, for example, the duty ratio of the pulse wave is changed, or the peak value is changed.

Instead of providing the transfer voltage control means 66, it is conceivable to provide control means for controlling the voltage transferred to the rotating section 82 to a predetermined value. It is easier and more efficient to control the input voltage on the fixed portion 81 side. Next, the rotary coupler 30 will be described. In the present embodiment, the fixed-side insulating plate 61 and the rotating-side insulating plate 62 are used as a common substrate for the power transfer unit 60 and the rotary coupler 30.
0 is formed on the fixed insulating plate 61 and the rotating insulating plate 62. As shown in FIG. 4, the rotary coupler 30 includes a lower rotary coupler 30a and an upper rotary coupler 30b having the same structure. The lower rotary coupler 30a is formed at the center of the fixed insulating plate 61, while the upper rotary coupler 30b is formed at the center of the rotary insulating plate 62. Lower rotating coupler 3
0a (upper rotary coupler 30b) is a fixed-side insulating plate 61
The non-grounded conductor plate 31 formed on one surface of the (rotational-side insulating plate 62), the conductor plate 32 formed so as to surround the non-grounded conductor plate 31, and the fixed-side insulating plate 61 (the rotation-side insulating plate 62). )
, A ground conductor plate 33 formed on the other surface, a resistor 34 for impedance matching, and a capacitor 3 for DC blocking.
5, a distributed constant type inductor 36, and a coaxial connector 3
And 7.

The impedance matching resistor 34 and the DC blocking capacitor 35 are connected in series between the ungrounded conductor plate 31 and the grounded conductor plate 33. One terminal of the DC blocking capacitor 35 is connected to the non-grounded conductor plate 31 through the fixed-side insulating plate 61 (rotating-side insulating plate 62). The inductor 36 is connected to the impedance matching resistor 3.
4 and a connection point between the DC blocking capacitor 35 and the ground conductor plate 33.

The rotary coupler 30 includes a lower rotary coupler 30a.
And the upper rotary coupler 30b are set apart from each other by a predetermined distance so that the respective non-grounded conductor plates 31 face each other. Also, the coaxial connector 37 of the lower rotary coupler 30a
Is connected to a cable line connected to the tuner 40, while a coaxial connector 37 of the upper rotary coupler 30b is connected to a cable line connected to the converter 20.

FIG. 8 is an equivalent circuit diagram of the rotary coupler 30.
Shown in Here, R ₀ is the output resistance on the converter 20 side, and RL is the load resistance on the tuner 40 side. Ungrounded conductor plate 31 of lower rotary coupler 30a, upper rotary coupler 3
The capacitor 38 is formed by the non-grounded conductor plate 31 of Ob and a gap therebetween. Also, the lower rotary coupler 3
0a, a capacitor is formed by the grounded conductor plate 33, the conductor plate 32, and the fixed insulating plate 61 existing therebetween, and the grounded conductor plate 33, the conductor plate 3 of the upper rotary coupler 30b.
2 and the rotating side insulating plate 61 existing between them form a capacitor. The capacitor 39 in FIG.
Is a combination of these two capacitors connected in series.

In each of the lower rotary coupler 30a and the upper rotary coupler 30b, stray capacitances C _S1 and C _S2 are formed between the ungrounded conductor plate 31 and the ground conductor plate 33, respectively. For the lower rotary coupler 30a, the stray capacity C _S1
Is sufficiently smaller than the capacitance C ₁ of the DC blocking capacitor 35, the capacitor C _S1 and the inductor 36
Is substantially connected in parallel between the ungrounded conductor plate 31 and the grounded conductor plate 33. Similarly, in the upper rotary coupler 30b, considering that the stray capacitance C _S2 is sufficiently smaller than the capacitance C ₂ of the DC blocking capacitor 35, the capacitor C _S2 and the inductor 36 are substantially non-grounded conductor plates. 31 and the ground conductor plate 33 are connected in parallel.

If the inductance of the inductor 36 is selected such that the stray capacitance C _S1 and the inductor 36 are in a parallel resonance state at the center value of the frequency of the IF signal, this parallel resonance circuit is in an open state and the stray capacitance C The short-circuit state of the signal line due to _S1 is removed. Similarly, if the inductance of the inductor 36 is selected so that the stray capacitance C _S2 and the inductor 36 are in a parallel resonance state, the parallel resonance circuit is opened, and the short-circuit state of the signal line due to the stray capacitance C _S2 is removed. Is done. As a result, the coupling loss of the rotary coupler 30 is greatly improved.

In the antenna device of the present embodiment, the first inductor provided on the fixed insulating plate and the second inductor provided on the rotating insulating plate and electromagnetically coupled to the first inductor are provided. When an alternating current flows through one inductor, induced electromotive force can be generated in the second inductor by a change in magnetic flux generated in the first inductor, so that power can be supplied from the fixed part side to the rotating part side in a non-contact manner. it can. For this reason, the voltage transferred to the rotating unit side can be used for the power supply of the converter. In addition, since this method is non-contact, there is no problem such as abrasion as in the case of using a conventional slip ring, and the structure is simple.

Further, a transfer voltage control means for monitoring the strength of the electromagnetic coupling between the first inductor and the second inductor, and controlling the alternating current flowing through the first inductor so that the voltage transferred to the rotating part is constant. With this arrangement, it is possible to correct the variation of the load, the variation of the interval between the fixed-side insulating plate and the rotating-side insulating plate, and the like, and to keep the voltage supplied to the rotating unit constant.

Further, in this embodiment, by providing a rotary coupler on the fixed-side insulating plate and the rotary-side insulating plate, the fixed-side insulating plate and the rotary-side insulating plate are shared by the power transfer unit and the rotary coupler. Therefore, the power transfer unit and the rotary coupler can be made compact. Note that the present invention is not limited to the above embodiment, and various modifications can be made within the scope of the gist.

In the above embodiment, the case where the first inductor and the second inductor are formed in a circular spiral pattern is described. However, for example, the first inductor or the second inductor may be formed in a rectangular spiral pattern. Also,
In the above embodiment, the case where the monitoring inductor is formed inside the first inductor has been described.
The monitoring inductor may be formed outside the first inductor. Further, the coil of the monitoring inductor may have a square pattern.

[0033]

As described above, according to the present invention, the first insulating plate provided on the fixed portion, the second insulating plate provided on the rotating portion opposite to the first insulating plate, By providing a first inductor provided on one insulating plate and a second inductor provided on the second insulating plate and electromagnetically coupled to the first inductor, when an alternating current flows through the first inductor, the first inductor Provided is an antenna device which can generate an induced electromotive force in a second inductor by a change in generated magnetic flux, and which can supply power from a fixed part side to a rotating part side in a non-contact manner with a simple configuration. Can be.

[Brief description of the drawings]

FIG. 1 is a schematic block diagram of an antenna device according to an embodiment of the present invention.

FIG. 2 is a schematic configuration diagram when the antenna device is mounted on an automobile.

FIG. 3 is a schematic partial sectional view of an antenna unit of the antenna device.

FIG. 4 is a schematic sectional view of a power transfer unit and a rotary coupler in the antenna device.

5A is a schematic plan view of a shared substrate provided in a rotating unit among two shared substrates of a power transfer unit and a rotary coupler shown in FIG. 4, and FIG. 5B is a shared substrate shown in FIG. It is a schematic rear view.

6A is a schematic plan view of a shared substrate provided in a fixed portion of the two shared substrates of the power transfer unit and the rotary coupler shown in FIG. 4, and FIG. 6B is a shared substrate shown in FIG. It is a schematic rear view.

FIG. 7 is an equivalent circuit diagram of the power transfer unit shown in FIG.

8 is an equivalent circuit diagram of the rotary coupler shown in FIG.

FIG. 9 is a diagram for explaining a rotary coupler and a slip ring used in a conventional antenna device.

[Description of Signs] 1 Antenna unit 2 Tuner unit 10 Antenna 20 Converter 30 Rotary coupler 30a Lower rotary coupler 30b Upper rotary coupler 31 Non-grounded conductor plate 32 Conductor plate 33 Grounded conductor plate 34 Impedance matching resistor Reference Signs List 35 DC blocking capacitor 36 Distributed constant type inductor 37 Coaxial connector 38, 39 Capacitor 40 Tuner 50 Azimuth control device 51 Reception level detector 52 Angular velocimeter 53 Control unit 54 Rotating mechanism unit 60 Power transfer unit 61 Fixed side insulating plate 62 Rotation Side insulating plate 63 First inductor 64 Second inductor 65 Rectifier circuit 65a Diode 65b Capacitor 66 Transfer voltage control means 66a Monitoring inductor 66b Control unit 70 Power supply device 81 Fixed unit 82 Rotating unit 83 Bearing

──────────────────────────────────────────────────続 き Continued on the front page (51) Int.Cl. ⁶ Identification symbol FI H04B 5/00 H04B 5/00 Z (72) Inventor Kazuo Kato 79-2 Kamoshida-cho, Aoba-ku, Yokohama-shi, Kanagawa Prefecture System uniques Inside the corporation

Claims (4)

[Claims] 1. An antenna apparatus comprising: a fixed portion; a rotating portion supported by the fixed portion so as to be rotatable around an axis perpendicular to the fixed portion; and a rotating mechanism for rotating the rotating portion. A first insulating plate provided on the fixed portion, a second insulating plate provided on the rotating portion so as to face the first insulating plate, and a first inductor provided on the first insulating plate. Provided on the second insulating plate, comprising a second inductor that is electromagnetically coupled with the first inductor, and when an alternating current flows through the first inductor, a change in magnetic flux generated in the first inductor is provided. An antenna device, wherein electric power is supplied from the fixed part side to the rotating part side by generating an induced electromotive force in the second inductor. 2. A monitoring means for monitoring the strength of electromagnetic coupling between the first inductor and the second inductor, and a voltage transferred to the rotating part based on a signal from the monitoring means is constant. 2. The antenna device according to claim 1, further comprising control means for controlling an alternating current flowing through the first inductor. 3. The monitoring device according to claim 2, wherein said monitoring means is a third inductor provided on said first insulating plate.
The antenna device as described in the above. 4. The antenna device according to claim 1, wherein a non-contact rotary coupler is provided on the first insulating plate and the second insulating plate.