JP2001074797A - Portable radio wave measuring instrument - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a portable radio wave measuring instrument which can measure unnecessary radiation power over a wide frequency range with a simple small-sized structure. SOLUTION: An absorbing material 11 is stuck to the internal surface of a closed metallic enclosure 10. In the enclosure 10, a turntable 13 and a reception antenna 17 are respectively set up on both sides in the longitudinal direction, and a transmission antenna is eccentrically attached to the upper surface of the turntable 13. In addition, the reception of direct waves is inhibited by making the angles of the transmission and reception antennas different from each other so that the planes of polarization of the antennas may become different from each other. Consequently, only the reflected wave of the electromagnetic wave emitted from the transmission antenna is made incident to the reception antenna, and the reflected wave is evenly disturbed in the enclosure 10. The probability distribution of an electric field intensity is found and the central position of the distribution is decided as the receiving level at the frequency.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a portable radio wave measuring device, and more particularly, to a wide band measuring device capable of measuring and inspecting EMC, EMI and the like.

[0002]

2. Description of the Related Art Measurement of unnecessary radiation power is one of the important factors in evaluating the characteristics of electronic devices and personal computers used in the MHz band and electronic communication devices in the GHz band. Conventionally, to measure such unnecessary radiated power, a measurement at an open site or a random field measurement method (RFM method) using an outdoor propagation environment is used.
Etc. are used.

In addition, a room such as an anechoic chamber and a shield room, each side of which is several meters, is used, and unnecessary radiation power is measured with an object to be measured installed in the room. .

[0004]

However, the above-mentioned conventional measuring method and the apparatus used therefor have the following problems. That is, in the case of an open site or outdoor random field measurement method, there is a problem that a large measurement space is required and a long measurement time is required. A place / environment that satisfies the conditions that can be measured is not available anywhere at any time, and is expensive. In the case of anechoic chambers and shielded rooms, although they can be made smaller than open sites, etc.
It is inevitable that the device will become larger.

SUMMARY OF THE INVENTION The present invention has been made in view of the above background, and has as its object to solve the above-mentioned problems and to measure unnecessary radiation power over a wide frequency range with a simple and compact structure. It is an object of the present invention to provide a portable radio wave measuring device that can perform the measurement.

[0006]

In order to achieve the above object, a portable radio wave measuring device according to the present invention comprises a closed metallic housing and a radio wave absorber attached to the inner surface of the housing. And a transmission unit and a reception unit arranged in the housing. One of the transmitting unit and the receiving unit has a turntable, and the antenna is mounted at an eccentric position of the turntable. Further, the transmitting unit and the receiving unit have different polarization planes, and the radio wave absorber is configured to match the antenna (claim 1).

[0007] With this configuration, a transmitting antenna and a receiving antenna are mounted on the transmitting unit and the receiving unit, respectively, and the rotary table is rotated. In this state, an electromagnetic wave is emitted (emitted) from the transmitting antenna and received by the receiving antenna. At this time, the electromagnetic waves emitted (radiated) from the transmission antenna provided in the transmission unit include those traveling toward the reception antenna and those traveling toward the inner wall surface of the housing. Since the polarization planes are different, even if there is an electromagnetic wave that travels straight toward the receiving antenna, the electromagnetic wave is not received by the receiving antenna as a direct wave. As a result, the reflected wave reflected on the inner wall surface is received by the receiving antenna.

In addition, since one of the antennas is rotated by the rotary table, the relative position between the transmitting and receiving antennas changes every moment. As a result, the reflected waves reflected at all angles are received by the receiving antenna, and are uniformly disturbed in the housing, so that a constant electric field intensity is obtained. Therefore, by receiving such a constant electric field strength by the receiving antenna, the unnecessary radiation power can be measured. Further, by forming the housing with metal, a shielding effect is also exerted.

Further, in an anechoic chamber, various measurements are made by minimizing the generation of reflected waves and detecting only direct waves. On the other hand, the portable radio wave measuring apparatus according to the present invention is fundamentally different in that direct waves are cut and various measurements are performed based on reflected waves. As a result, the radio wave absorber is provided for impedance matching of the antenna installed in the transmission / reception unit. Since the purpose is different, the characteristics to be used are different accordingly.

The radio wave absorber may be installed around the rotary table (claim 2). The impedance of the antenna varies depending on the positional relationship between the antenna and the side wall. Therefore, stable measurement and operation can be performed by taking impedance matching. In particular, the position of the antenna attached to the rotary table fluctuates, so that the function of the radio wave absorber is particularly required. Therefore, it is preferable to configure as defined in claim 2.

It is more preferable that the receiving unit uses an electric field sensor or an electric field probe as an antenna. Thus, by focusing on measuring the current (current intensity) from the original purpose of measuring radio waves, measurement of low frequency (large wavelength) can be performed even in a small space as in the present invention. It becomes possible. In particular, in the case of an electric field probe, the number of the electric field probes is arbitrary, and may be one or plural. In the case of a plurality, a more average level can be easily measured.

Further, as another solution, a closed metallic housing, a radio wave absorber attached to the inner surface of the housing, a transmitting unit and a receiving unit disposed in the housing are provided. Unit. The transmitting section has an antenna, the receiving section has a predetermined number of current detecting probes, one of the transmitting section and the receiving section has a turntable, and the antenna is located at an eccentric position of the turntable. Alternatively, the current detection probe is attached. Further, the radio wave absorber matches the antenna (claim 4). The number of current detection probes may be set arbitrarily, and may be one or more.

The basic operation principle is the same as that of the first aspect. In the present invention, by providing the current detection probe in the receiving unit, the current (magnitude of the current) is directly detected, and the radiation power is estimated therefrom. By detecting the current in this way, a large wavelength can be measured even in a small space such as a portable box. When the current detection probe is mounted on the rotary table, the average level of the current can be easily measured, and more accurate measurement can be performed.

The transmitting section and the receiving section in the present invention do not necessarily have to mount an antenna. That is, the antenna may be attached at the time of the final measurement, so that an attachment member such as a connector may be provided. Further, the rotary table may be of any type as long as it can rotate the antenna regardless of the name. Turntable is a synonym.

[0015]

FIG. 1 shows a preferred embodiment of a portable radio wave measuring apparatus according to the present invention. As shown in FIG. 1, a rectangular parallelepiped housing 10 is provided, and all six surfaces of the housing 10 are formed of metal plates. The dimensions of the housing 10 are 50 cm × 50 cm × 100 c
m. It is to be noted that the dimensions are not limited to the above, and that the dimensions can be arbitrarily changed in the vertical and horizontal directions.

However, for example, 3 m × 3
Although there is a case where the size is about mx 2 m, the dimensions of the housing of the portable radio wave measuring device of the present invention do not include a case that is large. In other words, it is not a fixed installation type, but a mobile (portable)
This is a size that can be used. Further, in the present embodiment, all six surfaces are made of metal plates, but a part or all of them may be made of a mesh.

A ferrite tile absorber 11 is attached to the entire inner surface of the housing 10. This ferrite tile absorber 11 is used for impedance adjustment of an antenna mounted on the present measuring device. Therefore, the absorption characteristics of the ferrite tile absorber only need to absorb about 10 to 20 dB (preferably, 10 to 15 dB) over the frequency range to be measured, and conversely, those that absorb too much are not suitable.

As an example, one having an absorption characteristic as shown in FIG. 2 can be used. In this example, the second marker (157.222 MHz) has a large absorption of 40 dB, but the first marker (36.734 MHz) has a large absorption of 200.011 dB and the third marker (395.525).
MHz at 19.983 dB, the fourth marker (6
27.492 MHz), it becomes 15 dB, and the whole (10
１０００1000 MHz) within approximately 10 to 20 dB.

The radio wave absorber used in an ordinary anechoic chamber or the like is provided so that only the direct wave emitted from the transmitting antenna is received by the receiving antenna and the reflected wave reflected on the side wall of the anechoic chamber is not received. The function is essentially different from that which literally absorbs the radio wave that has reached the side wall and does not reflect it.

On the bottom surface of the housing 10, a turntable 13 is disposed at one end in the longitudinal direction. The rotating table 13 serves as a transmitting unit, and the transmitting antenna 15 is installed on the rotating table 13 during measurement. At this time, the transmitting antenna 15 is installed at an eccentric position shifted from the center of the rotary table 13. Then, the electromagnetic wave is emitted from the transmission antenna 15 while rotating the rotary table 13. By emitting the radio wave while rotating in this manner, the emission position of the transmission antenna 15 changes every moment.

On the other hand, of the two longitudinal side surfaces of the housing 10,
On the side where the turntable 13 is not installed, the receiving antenna 17
Is installed. Then, the angles of the transmitting antenna 15 and the receiving antenna 17 are made different from each other (see FIG. 3B) so that the direct wave of the electromagnetic wave emitted from the transmitting antenna 15 does not directly enter the receiving antenna 17. That is, the plane of polarization between transmission and reception is made different (shifted by 45 degrees in the illustrated example). Thus, the electromagnetic wave emitted from the transmission antenna 15 is reflected at least once on the inner surface of the housing 10 and is received by the reception antenna 17.

In addition, as described above, the transmission antenna 15
Is rotating with the rotation of the turntable 13, the relative positional relationship between the transmitting antenna 15 and the receiving antenna 17 is different. Further, the transmitting antenna 15 and the housing 10
Also has a different relative positional relationship with the inner surface. As a result, the path of the reflected wave received by the receiving antenna 17 is also different,
Can be received by the receiving antenna 17, and the electromagnetic waves can be uniformly disturbed.

Further, the receiving antenna 17 uses an electric field sensor or an electric field probe and is used in a non-resonant range. By focusing on measuring current (current intensity) from the original purpose of measuring radio waves, low frequency (large wavelength) measurement can be performed even in a small space as in the present invention. It becomes possible.

An output cable 20 penetrating the side surface of the housing 10 to which the receiving antenna 15 is attached is disposed. One end of the output table 20 is connected to the receiving antenna 17 and the other end is connected to the measuring antenna. It is connected to the device 22.

The measuring device 22 obtains the electric field intensity distribution for each frequency of the received reflected wave, and calculates the median value (50
% Position), and an arithmetic process is performed such that the calculated value is used as the electric field strength (reception level) of each frequency. The calculation result is printed out on an output device (not shown) or stored in a storage device.

* Experimental Results A spherical dipole antenna is installed on the rotary table 13 as a transmitting unit. Then, the electromagnetic wave is measured while rotating it. The measurement range is in the range of 30 to 1000 MHz. As a result, characteristics as shown by a solid line in FIG. 3 were obtained. When the characteristics of the anechoic chamber with respect to the frequency were obtained under the same conditions, the characteristics shown by the two-dot chain line in FIG. As is clear from the figure, a correlation was obtained between the portable radio wave measuring apparatus and the anechoic chamber, and it was confirmed that the portable radio wave measuring apparatus of the present invention can be put to practical use.

In the above-described embodiment, the rotary table is arranged on the transmitting antenna side, but a rotary table may be arranged on the receiving table side. Further, the example in which the ferrite tile absorber is attached to the entire inner surface of the housing 10 has been described, but the present invention is not limited to this, and may be provided at least around the side on which the rotary table is installed. Furthermore, it is a matter of course that a current detecting probe may be used instead of the receiving antenna 17, and the number and positions of the probes are arbitrary.

Furthermore, in the above-described embodiment, the ferrite absorber 11 is attached to a predetermined side surface of the housing 10, but the structure at the time of attachment is fixed by an adhesive or the like so that it cannot be detached. Alternatively, it may be detachably attached.

As a detachable structure, for example, as shown in FIG. 4A, a screw hole 10a is provided on the side surface of the housing 10, and the ferrite absorber 11 is provided at the installation position of the screw hole 10a. The ferrite absorber 11 can be fixed by the screw. This makes it possible to remove the ferrite absorber 11 and attach another absorber by loosening the screw,
By mounting a ferrite absorber suitable for the conditions, more accurate measurement is possible. Further, as shown in FIG. 2B, in a state where the ferrite absorber 11 is already attached to the side surface of the housing 10, a metal plate or another absorber 24 may be detachably attached.

As shown in FIG. 5, a metal scatterer 25 may be provided at a predetermined position on the inner side surface of the housing 10. As the metal scatterer 25, a triangular wave type may be provided on the entire surface as shown in FIG. 5A, or a rectangular body may be arranged at an appropriate interval as shown in FIG. Various structures can be adopted. Providing the metal scatterer 25 in this manner is preferable because radio waves emitted from the transmitting antenna are likely to be irregularly reflected when reflected on the side surface of the housing 10 and more uniform reflected waves reach the receiving unit side.

[0031]

As described above, in the portable radio wave measuring apparatus according to the present invention, since the case, that is, the size is small, if a direct wave is received, the reception level is too strong (compared with the reflected wave). Although measurement is no longer possible, it is configured to suppress the reception of direct waves as much as possible, and by reflecting within the housing,
Uneven radiation can be obtained by uniformly disturbing the inside of the housing to obtain a constant electric field strength.The constant electric field strength can be received by the receiving antenna or the current on the receiving unit side can be detected by the current detection probe. Measurement of electric power becomes possible. Also,
Forming the housing with metal also exerts a shielding effect. Therefore, it is possible to measure the unnecessary radiation power over a wide frequency range with a simple and small structure.

[Brief description of the drawings]

FIG. 1 is a diagram showing a preferred embodiment of a portable radio wave measuring device according to the present invention.

FIG. 2 is a diagram illustrating frequency characteristics of a ferrite tile absorber.

FIG. 3 is a diagram showing experimental results showing the effects of the present invention.

FIG. 4 is a diagram showing a modification.

FIG. 5 is a view showing still another modified example.

[Explanation of symbols]

 Reference Signs List 10 housing 11 ferrite tile absorber 13 turntable 15 transmitting antenna 17 receiving antenna 20 output cable 22 measuring device

 ──────────────────────────────────────────────────続 き Continuing on the front page (72) Manabu Teranishi 5-36-11 Shimbashi, Minato-ku, Tokyo Inside Fuji Electric Chemical Co., Ltd. (72) Hiroaki Ono 5-36-11 Shimbashi, Minato-ku, Tokyo Fuji Inside Electrochemical Co., Ltd. (72) Inventor Makoto Ishikura 5-36-11, Shimbashi, Minato-ku, Tokyo Inside Fuji Electric Chemical Co., Ltd. Inventor Tsutomu Kikui 5-7-2 Yashio, Shinagawa-ku, Tokyo F-term in the Telecom Engineering Center 5J020 BD02 EA02 EA03 EA10 5J047 AA04 AA12 AB06 BF01 BF10 FD10

Claims (4)

[Claims] 1. A closed metal housing, a radio wave absorber attached to an inner surface of the housing, a transmitting unit and a receiving unit disposed in the housing, wherein the transmitting unit and the One of the receiving units has a rotary table, an antenna is mounted at an eccentric position of the rotary table, the transmitting unit and the receiving unit have different polarization planes, and the radio wave absorber is connected to the antenna. A portable radio measurement device characterized by matching. 2. The portable radio wave measuring apparatus according to claim 1, wherein the radio wave absorber is installed around the rotary table. 3. The portable radio wave measuring apparatus according to claim 1, wherein the receiving unit uses an electric field sensor or an electric field probe as an antenna. 4. A closed metal casing, a radio wave absorber attached to an inner surface of the casing, a transmitting unit and a receiving unit disposed in the casing, wherein the transmitting unit is an antenna. The receiving unit has a predetermined number of current detecting probes, and one of the transmitting unit and the receiving unit has a rotating table, and an antenna or the current detecting probe is provided at an eccentric position of the rotating table. The portable radio wave measuring apparatus, wherein the radio wave absorber matches the antenna.