JPH06326489A - Radio wave anechoic chamber - Google Patents

Abstract

PURPOSE:To provide a radio wave anechoic chamber which can reduce the reflection at the coupling part between the ferrite radio wave absorber arranged at a waveguide part and the radio wave absorber of resistance loss material of a receiving part which absorber is arranged contouiously to the ferrite absorber, and has excellent uniformity of electric field. CONSTITUTION:The wall surface of a receiving part 12 is covered with a radio wave absorber 14 composed of compound type loss material which is composed of resistance loss material or formed by combining ferrite tile with resistance loss material. In a taper type radio wave anechoic chamber 10 with which the receiving part 12 is connected via a tapered waveguide part 15, at least a part of the ceiling surface and the side wall surface of the waveguide part is constituted of a ferrite radio wave absorber 16. Radio wave absorber 20 which smoothly changes electrically or physically is formed in the conversion part 19 between the ferrite radio wave abosorber 16 of the waveguide part 15 and the radio wave absorber 14 of the receiving part 12. Further, an obliquely incident radio wave absorber 22 for smooth adjustment from the viewpoint of radio wave is provided in a boundary part 21.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention is for measuring the characteristics of receiving antennas and mobile communication antennas mounted on automobiles and aircraft, and for evaluating unnecessary radio waves and noise generated from electronic equipment and externally. The present invention relates to an anechoic chamber used for measuring EMI and EMS, which tests the influence of radio waves from EMI on electronic devices.

[0002]

2. Description of the Related Art Conventionally, as an environment for measuring the radio wave propagation characteristics of an antenna, measuring the noise generated from an electronic device, and testing the influence of an interference wave from the outside on the electronic device, weather conditions, temperature and humidity conditions have been used. A stable and highly reliable room that can remove the influence of external noise is desired. The anechoic chamber is one in which the wall surface, ceiling, and floor surface are covered with an electromagnetic wave absorber in order to provide such an indoor space, and its superiority is well known and widely applied.

As a characteristic of such an anechoic chamber, it is a major issue to realize a free space in the room free from radio wave obstructions, and it is reflected from the side wall surface, ceiling surface and floor surface of the room. It is desired to reduce unnecessary electromagnetic wave energy and to obtain excellent electric field uniformity in the receiver.

Incidentally, the radio wave propagation characteristic in free space means that when the transmission antenna, which is a radio wave generation source, is modeled as a point wave source, the electric field of the radiated radio wave spreads concentrically and propagates sufficiently. In addition, a so-called plane wave having a uniform size and phase in a plane is realized in a limited region far away, whereby electric field uniformity is ensured. However, if the distance is sufficiently far, the electric field strength decreases in inverse proportion to the distance as the propagation distance increases.

The anechoic chamber has, in addition to a general rectangular parallelepiped shape, a shape in which a wall surface, a ceiling surface, and a floor surface in an intermediate region between the transmitting portion and the receiving portion are widened to reduce reflection from them. A tapered anechoic chamber is used in which a transmitter in a narrow space and a receiver in a wide space are connected by a tapered waveguide.

The taper type anechoic chamber is economical because it has a smaller volume than the rectangular anechoic chamber when the same distance between transmission and reception is taken. Further, due to the taper angle of the waveguide portion, there is almost no influence of reflection from the side wall portion like the radio wave radiation state in the horn antenna, and the path difference between the side wall reflected wave and the direct wave can be reduced in the transmitting portion, so that the phase difference is Since it is extremely small, the electric field uniformity in the receiving section is excellent.

FIG. 10 is a plan view schematically showing the conventional tapered anechoic chamber of this kind, and FIG. 11 is a sectional view taken along line XI-XI of FIG.

As shown in these figures, the conventional tapered anechoic chamber has a tapered planar shape and a sectional shape, and all the wall surfaces, that is, the side wall surfaces 100,
A ceiling surface 101 and a floor surface 102 are covered with a pyramid-shaped or wedge-shaped radio wave absorber 103 made of a carbon-containing foam which is a resistance loss material. A horn antenna type transmitting structure 105 having a waveguide is provided at the end of the transmitting unit 104 in a narrow space. This transmitter 104
And the receiving section 106 having a large space, the tapered waveguide section 10
They are connected by 7. The waveguide unit 107 has a side wall surface, a ceiling surface, and a floor surface that are different from the transmitting unit 104 to the receiving unit 10.
The taper shape is such that it gradually widens toward 6 and the cross-sectional area gradually increases.

[0009]

Since the conventional taper type anechoic chamber uses the electromagnetic wave absorber made of the resistance loss material, the length of the electromagnetic wave absorber should be absorbed in order to obtain excellent electromagnetic wave absorption characteristics. It must be at least ½ of the wavelength of the frequency. This is because, if the frequency to be absorbed is 100 MHz, for example, the length of the absorber will be 1.5 m or more, the size of the building that constitutes the anechoic chamber will be significantly large, and it will be economically disadvantageous and each wall surface The volume of the effective space sandwiched between the tips of the radio wave absorber from the above becomes extremely small.

When an antenna mounted on a ground moving body such as an automobile receives a radio wave in a mounted state, it receives a radio wave in which a reflected wave from the ground and a direct wave from a transmission source are combined. However, in the conventional taper type anechoic chamber as described above, since the floor surface is also constituted by the electromagnetic wave absorber, there is no reflected wave from the ground and only the direct wave is received. Therefore, the radio wave characteristic received in the anechoic chamber and the radio wave characteristic in the practical state are different from each other.

Further, in the conventional taper type anechoic chamber, the transmission frequency range of the transmitting section is limited to the frequency range of the waveguide. For this reason, when performing wideband measurements with the recent expansion of radio wave usage and widening of available frequencies, it is necessary to prepare a plurality of transmitters having different frequency bands and exchange them. Causes an inconvenience that not only increases the financial burden but also requires a great deal of labor for replacement.

Instead of the electromagnetic wave absorber made of a resistance loss material, a part of the wall surface of the waveguide is covered with a ferrite electromagnetic wave absorber having a large magnetic loss and exhibiting an excellent electromagnetic wave absorbing performance in a thin thickness. By doing so, it becomes possible to secure economically inexpensive and effective space. However, with such a configuration, impedance mismatching occurs at the boundary portion between the radio wave absorber made of the resistance loss material and the ferrite radio wave absorber having a different radio wave absorption principle, and radio waves are reflected.

Therefore, the present invention solves the above-mentioned problems of the prior art, and a radio wave is generated by a ferrite wave absorber provided in the waveguide section and a resistance loss material which is arranged continuously to the ferrite wave absorber and constitutes the receiving section. It is intended to provide an anechoic chamber capable of reducing reflection at a portion coupled to an absorber and having more excellent electric field uniformity.

[0014]

According to the present invention, the wall surface of the receiving portion is covered with a radio wave absorber made of a resistance loss material or a composite loss material in which a ferrite tile and a resistance loss material are combined, and the receiving portion is covered. The anechoic chamber of the taper type in which the two are connected by a tapered waveguide part has at least a part of the ceiling surface and side wall surface of the waveguide part made of a ferrite electromagnetic wave absorber, and the ferrite electromagnetic wave absorber of the waveguide part is And a converter formed of a radio wave absorber that is electrically or physically changed so as to be smooth at the coupling portion between the radio wave absorber and the reception unit,
An oblique-incidence electromagnetic wave absorber is provided at the boundary between the ferrite electromagnetic wave absorber of the waveguide section and the electromagnetic wave absorber forming the above-mentioned conversion section to smoothly adjust the electromagnetic wave.

The floor surfaces of the waveguide and the receiving portion are flat with respect to the ground, and the floor surfaces of the receiving portion and the waveguide are composed of a ground equivalent floor formed by combining a ferrite tile and a conductive film. Is preferred.

It is also preferable that the coupling position of the waveguide section and the transmitting section on the ceiling surface and the coupling position of the waveguide section and the transmitting section on the side wall surface are different from each other.

It is also an embodiment of the present invention to dispose an independent transmitting broadband antenna in the transmitting section.

[0018]

[Function] A radio wave absorber made of a resistance loss material or a reception part covered with a radio wave absorber made of a composite loss material obtained by combining a ferrite tile and a resistance loss material, and a waveguide part covered with a ferrite wave absorber. Suppresses reflection due to sudden impedance mismatch due to completely different radio wave absorption principle by providing a conversion part made of a radio wave absorber that is electrically or physically changed to be smooth at the coupling part with . Also, by providing an oblique incident wave absorber at the boundary between the ferrite wave absorber of the wave guide section and the wave absorber forming the above-mentioned conversion section and adjusting the wave smoothly, reflection due to impedance mismatch is achieved. Suppress.

Further, by making the coupling position of the waveguide section and the transmission section on the ceiling surface different from the coupling position of the waveguide section and the transmission section on the side wall surface, the boundary between the waveguide section and the transmission section is different. It can be configured so that the opening cross-sectional area at the part gradually changes, and also in this respect the impedance mismatch can be improved,
Reflection can be suppressed.

Further, in order to form the same environment as a radio environment in a practical state in the field, the floor surfaces of the receiving section and the waveguide section are constituted by a ground equivalent floor having characteristics equivalent to the ground in terms of radio waves. Further, a ferrite wave absorber is arranged on part or all of the ceiling surface and the side wall surface of the waveguide section instead of the wave absorber made of a resistance loss material having a length of ½ or more of the wavelength. The ferrite electromagnetic wave absorber has a large magnetic loss and excellent electromagnetic wave absorption performance at a thickness of 1/50 to 1/200 of the wavelength, so that a wider effective space can be secured and the electromagnetic wave anechoic chamber can be secured. Can be formed at low cost.

[0021]

EXAMPLES Examples of the present invention will be described in detail below. Figure 1
2 is a plan view schematically showing the configuration of an embodiment of the anechoic chamber of the present invention, and FIG. 2 is a sectional view taken along line II-II of FIG.

As shown in these figures, the tapered anechoic chamber 10 has one end as a transmitting portion 11 having a narrow space and the other end having a receiving portion 12 having a wide space.

The receiving unit 12 suppresses unnecessary reflected waves from the wall surface as much as possible in order to reproduce the situation in which the infinite space continues for the transmitted radio waves, and only the traveling wave component is obtained in the receiving area. Is designed to. Receiver 12
Of the four wall surfaces other than the floor surface, that is, the left and right side wall surfaces 12a and 12b, the ceiling surface 12c, and the back wall surface 12d are the electromagnetic wave absorber 14 made of the resistance loss material, or the ferrite wave absorber and the resistance loss material are combined. It is covered with a composite type electromagnetic wave absorber 14 formed by the following. Further, the transmitter 11 is designed to transmit the single mode radio wave as much as possible by suppressing unnecessary reflected waves from the wall surface thereof.
The four wall surfaces other than the floor surface of the transmitter 11, that is, the left and right side wall surfaces 11a and 11b, the ceiling surface 11c, and the inner wall surface 11d are the electromagnetic wave absorber 13 made of a resistance loss material, or the ferrite electromagnetic wave absorber and the resistance loss material. It is covered with a composite type electromagnetic wave absorber 13 formed by combining and. These radio wave absorbers 1
3 and 14 are formed in a pyramid shape, a wedge shape, or a plate shape having different material constants in the thickness direction.

If a composite type electromagnetic wave absorber in which a ferrite electromagnetic wave absorber and a resistance loss material are combined is used as the electromagnetic wave absorbers 13 and 14, excellent electromagnetic wave absorption characteristics can be obtained from a low frequency and only the resistance loss material is used. Compared with the above case, a length equal to or less than ½ can provide the same or higher absorption characteristics. As a result, not only the effective space in the anechoic chamber can be expanded, but also the building itself can be made small and the cost can be largely reduced as a whole.

The transmitter 11 and the receiver 12 are connected by a tapered waveguide 15. The waveguide unit 15 minimizes the reflection of the single mode radio wave transmitted from the transmission unit 11 due to the local non-uniformity of the wall surface, and is close to the radio wave propagation characteristics of the far region in the free space with a short transmission distance. Is designed to obtain the highest possible radio wave attenuation effect. Three wall surfaces of the waveguide portion 15 excluding the floor surface, that is, the left and right side wall surfaces 15a and 15b, and the ceiling surface 1
All or a part of 5c is formed of a flat ferrite wave absorber 16. This ferrite wave absorber 16
Has a large magnetic loss, has a large radio wave attenuation effect in a wide band, and has a wavelength of 1/50 to 1/20.
Even if the thickness is 0, it has excellent electromagnetic wave absorption performance, so that it can be made extremely thin. As a result, a uniform electric field can be obtained with a shorter propagation distance, a large effective space can be secured, and an effective anechoic chamber can be realized in an economical small building.

The transmitter 11, the receiver 12, and the waveguide 15
The floor surfaces 11e, 12e, and 15e have a flat structure parallel to the ground. This is because the ground is generally flat. Furthermore, these floor surfaces 11e, 12e, and 15e are ground equivalent floors having a characteristic equivalent to the ground in terms of radio waves by combining a ferrite tile and a conductive film, except for a part.

An independent array type antenna 17 having a wide band characteristic is arranged in the central portion of the transmitter 11.
The entire transmitter 11 is configured as a broadband transmitter.
Therefore, it is not necessary to prepare a plurality of transmission units for each frequency band, and the labor for exchanging them can be saved.

At the center of the receiver 12, there is provided a turntable on which an object to be measured, for example, a car W is placed.

The electromagnetic wave absorber 14 and the waveguide 15 of the receiver 12
The converter 19 coupled with the radio wave absorber 16 is provided with the radio wave absorber 20 so as to smoothly change electrically or physically. A radio wave absorber 22 is provided on the radio wave absorber 14 at a boundary portion 21 between the conversion unit 19 and the waveguide unit 15 so as to project obliquely in the direction of the wave guide unit 15, whereby the radio wave absorber of the reception unit 12 is absorbed. The body 14 and the radio wave absorber 16 of the wave guide portion 15 are smoothly coupled in a radio wave manner so that impedance mismatch does not occur at the boundary portion 21.

3 and 4 show these electromagnetic wave absorbers 20.
3A and 3B are views for explaining the structure of the oblique incident electromagnetic wave absorber 22 and are a plan view and a cross-sectional view showing in detail the conversion unit 19 and the boundary portion 21 of FIGS. 1 and 2, respectively. 5 and 6 explain another configuration example of the radio wave absorber 20 and the oblique incident radio wave absorber 22, and correspond to the conversion unit 19 and the boundary portion 21 of FIGS. 1 and 2. It is the top view and sectional view which show each part in detail.

As shown in these drawings, the side wall surfaces 19a and 19b and the ceiling surface 19c of the conversion section 19 are covered with the above-mentioned radio wave absorber 20. By arranging the radio wave absorber 20 so as to change smoothly electrically or physically, the impedance change between the absorber 14 of the receiver 12 and the absorber 16 of the waveguide 15 is moderated. As a result, the structure suppresses the reflection at that portion. Then, in the boundary portion 21, the radio wave absorber 20 located closest to the waveguide portion 15 of the radio wave absorbers 20 is preferably a pyramid-shaped or wedge-shaped radio wave absorber 22 made of the same material. Are provided so as to project obliquely in the direction of the waveguide section 15, and such an oblique incident electromagnetic wave absorber 22 having a double structure has an impedance between the absorber 20 of the conversion section 19 and the absorber 16 of the waveguide section 15. By making the change more gradual, the structure is such that reflection at that portion is suppressed.

Further, as is clear from the difference between the distance D ₁ in FIG. ₁ and the distance D _{2 in} FIG.
5 and the coupling part of the transmitter 11 and the waveguide 1 on the ceiling surface
5 and the connecting position of the transmitter 11 are different from each other. Therefore, the opening cross-sectional area gradually changes at the boundary between the waveguide 15 and the transmitter 11. As a result, the impedance mismatch at this boundary can be improved, and reflection can be suppressed.

7 and 8 show a conventional tapered anechoic chamber without the electromagnetic wave absorber 20 and the oblique incident electromagnetic wave absorber 22 in the converter 19 and the electromagnetic wave absorber 20 and the oblique incident electromagnetic wave absorber 22 in the converter 19, respectively. The variation value characteristics of the electric field with respect to the frequency of the vertically polarized wave in the provided taper anechoic chamber 10 of the above-described embodiment are shown. This characteristic shows the electric field distribution in a circle with a height of 1.3 m and a diameter of 6 m.

As shown in these figures, in the conventional anechoic chamber, the maximum-minimum electric field fluctuation value fluctuates within the range of 1 to 4.2 dB, but in the taper type anechoic chamber of this embodiment, the maximum-minimum value. The electric field fluctuation value of is about 2 to 3.4 dB,
Very stable.

Further, according to the present embodiment, in order to make the conditions identical to the outdoor radio wave propagation environment, a ground equivalent floor that is radio equivalent to the ground is provided in the waveguide section 15 and the receiving section 12, Direct wave from the transmitter 11 and the floor surface 15e of the waveguide 15
The reflected wave from is combined in the same manner as in the practical state and enters the receiving unit 12 to realize a reception state close to radio wave propagation in the field.

When the floor surface is a ground equivalent floor that is radio-equivalent to the ground, the direct wave from the transmitter 11 and the reflected wave from the ground equivalent floor interfere with each other and have ripples having large maximum and minimum values. This may cause a phenomenon, and it is necessary to prevent electric field nonuniformity due to mutual interference. For that purpose, it is necessary to select the distance between the transmitting and receiving so that the difference between the phase of the reflected wave and the phase of the direct wave is at least ½ wavelength or less.

As shown in FIG. 9, the height of the transmitting antenna 90 is h ₁ , the height of the receiving antenna 91 is h ₂ , the linear distance between the transmitting and receiving antennas is l ₀ , the reflecting distance between the transmitting and receiving antennas is l ₁ , and If l ₂ and the wavelength are λ, then this is l ₁ + l ₂ −l ₀ = √ {l ₀ + (h ₁ + h ₂ )} − l ₀
The relationship of ≧ λ / 2 is satisfied. For example, the transmitting antenna 90
The height h ₁ of the antenna and the height h ₂ of the receiving antenna 91 is h ₁
When + h ₂ = 3m, the linear distance between the transmitting and receiving antennas is
₀ is l ₀ ≧ 2.25 m when the frequency is 100 MHz
Therefore, if the frequency is 300 MHz, then l ₀ ≧ 8.75
m, and if the frequency is 600 MHz, then l ₀ ≧ 17.
It will be 9m. When h ₁ + h ₂ = 4 m, l ₀ ≧ 4.58 m when the frequency is 100 MHz, l ₀ ≧ 15.75 m when the frequency is 300 MHz, and l ₀ ≧ 32 m when the frequency is 600 MHz. Setting to satisfy such a condition realizes a radio wave propagation environment in which the reception antenna receives a radio wave from a transmission point that is practically distant.

[0038]

As described in detail above, according to the present invention, a radio wave absorber made of a resistance loss material forming a wall surface of a receiving portion or a composite loss material obtained by combining a ferrite tile and a resistance loss material is used. At the coupling part between the electromagnetic wave absorber and the ferrite electromagnetic wave absorber forming the wall surface of the waveguide,
Providing a converter consisting of an electromagnetic wave absorber that is changed to be electrically or physically smooth, and at the boundary between the ferrite wave absorber of the wave guide and the electromagnetic wave absorber forming the converter. Since the boundary impedance is matched by providing a grazing incidence radio wave absorber and adjusting the radio wave smoothly, it is possible to eliminate reflection at this part and obtain better electric field uniformity. It is possible to provide an anechoic chamber having characteristics close to propagation.

Further, by setting the floor surfaces of the waveguide and the receiving section to the ground equivalent floor, it is possible to obtain characteristics close to the radio wave propagation in the field mounting. Moreover, by constructing at least a part of the ceiling surface and side wall surface of the waveguide part with a ferrite electromagnetic wave absorber, effective electromagnetic wave attenuation can be obtained and excellent electric field uniformity can be obtained in a shorter distance. Not only is it excellent, but also because it can be configured with an extremely short electromagnetic wave absorber, a wide space can be secured, and an economically inexpensive anechoic chamber can be provided. Also, by placing a wideband antenna in the transmitter,
Since it is not necessary to prepare a plurality of transmitters for each frequency band, the cost is economically low and the labor for exchanging the transmitters can be saved, so that significant labor saving and speedup can be achieved.

[Brief description of drawings]

FIG. 1 is a plan view schematically showing the configuration of an embodiment of an anechoic chamber of the present invention.

FIG. 2 is a sectional view taken along line II-II in FIG.

FIG. 3 is a plan view showing in detail a boundary portion of FIG.

FIG. 4 is a cross-sectional view showing a boundary portion of FIG. 2 in detail.

FIG. 5 is a plan view showing in detail a portion corresponding to the boundary portion of FIG. 1 in another embodiment of the present invention.

FIG. 6 is a sectional view showing in detail a portion corresponding to the boundary portion of FIG. 2 in another embodiment of the present invention.

FIG. 7 is a characteristic diagram showing an electric field fluctuation value in a conventional technique.

FIG. 8 is a characteristic diagram showing electric field fluctuation values in the examples of FIGS. 1 and 2.

FIG. 9 is a model diagram of radio wave propagation showing a relationship between a direct wave and a reflected wave of a radio wave.

FIG. 10 is a plan view schematically showing a conventional tapered anechoic chamber.

11 is a sectional view taken along line XI-XI of FIG.

[Explanation of symbols]

10 Tapered Anechoic Chamber 11 Transmitter 11a, 11b, 12a, 12b, 15a, 15b, 1
9a, 19b Side wall surface 11c, 12c, 15c, 19c Ceiling surface 11d, 12d, Back wall surface 11e, 12e, 15e Floor surface 12 Receiver 13, 14 Radio wave absorber 15 Waveguide 16 Ferrite radio wave absorber 17 Array type antenna 18 Turntable 19 Converter 20 Electromagnetic wave absorber 21 Boundary 22 Oblique incident electromagnetic wave absorber

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Toshiaki Kobayashi 1-13-1, Nihonbashi, Chuo-ku, Tokyo TDK Corporation (72) Inventor Shingo Seki 3-5-11, Doshomachi, Chuo-ku, Osaka-shi, Osaka No. Nippon Sheet Glass Co., Ltd. (72) Inventor Kazuhiko Ogawa 3-5-11 Doshumachi, Chuo-ku, Osaka City, Osaka Prefecture Japan Plate Glass Co., Ltd. (72) Inventor Harunori Murakami 3-5, Doshomachi, Chuo-ku, Osaka Prefecture, Osaka No. 11 within Nippon Sheet Glass Co., Ltd. (72) Inventor Keisuke Tanaka 3-5-11 Doshomachi, Chuo-ku, Osaka City, Osaka Prefecture Within Nippon Sheet Glass Co., Ltd.

Claims (4)

[Claims] 1. A wall of the receiving portion is covered with an electromagnetic wave absorber made of a resistance loss material or an electromagnetic wave absorber made of a composite loss material in which a ferrite tile and a resistive loss material are combined, and the receiving portion is tapered. A anechoic chamber of a taper type connected to a waveguide part, wherein at least a part of a ceiling surface and a side wall part of the waveguide part is composed of a ferrite electromagnetic wave absorber, and the ferrite electromagnetic wave absorber of the waveguide part is connected to the receiving part. As a method of coupling the electromagnetic wave absorber to the electromagnetic wave absorber, a conversion unit including an electromagnetic wave absorber that is changed to be electrically or physically smooth is provided, and the ferrite electromagnetic wave absorber of the waveguide unit and the conversion unit are formed. An anechoic chamber characterized in that an obliquely incident electromagnetic wave absorber is provided at the boundary with the electromagnetic wave absorber to smoothly adjust the electromagnetic wave. 2. A ground-equivalent floor in which the floor surfaces of the waveguide and the receiving section are flat with respect to the ground, and the floor surface of the receiving section and the waveguide is a combination of a ferrite tile and a conductive film. The anechoic chamber according to claim 1, characterized in that 3. The coupling position of the waveguide section and the transmission section on the ceiling surface and the coupling position of the waveguide section and the transmission section on the side wall surface are different from each other.
Or the anechoic chamber described in 2. 4. The anechoic chamber according to claim 1, wherein an independent wideband antenna for transmission is arranged in the transmitting unit.