JP2008032692A - Electromagnetic wave measuring device - Google Patents

Abstract

The present invention relates to an electromagnetic wave measuring box having an electromagnetic wave absorber on the inner surface, and a transmitter for transmitting electromagnetic waves and a receiver for receiving transmitted electromagnetic waves with a predetermined interval between one and the other. An object of the present invention is to provide an electromagnetic wave measuring apparatus that can be installed at a predetermined position with good reproducibility.
A transmission antenna 32 for transmitting electromagnetic waves and a reception antenna 31 for receiving transmitted electromagnetic waves are installed in an electromagnetic wave measuring box 10 having an electromagnetic wave absorber 13 on an inner surface at a predetermined interval. An electromagnetic wave measuring apparatus 1 for measuring an electromagnetic wave received by an antenna 31, comprising a circular opening 15a and a circular plate portion 15b for allowing the receiving antenna 31 to be inserted up to a receiving antenna installation position 15 in the electromagnetic wave measuring box 10, The circular plate portion 15b is configured to permit insertion of the reception antenna 31 in a direction orthogonal to a straight line connecting the transmission antenna 32 and the reception antenna 31.
[Selection] Figure 4

Description

  In the present invention, a transmitter for transmitting electromagnetic waves and a receiver for receiving transmitted electromagnetic waves are installed at predetermined intervals inside an electromagnetic wave measurement box having an electromagnetic wave absorber on the inner surface, and the receiver receives the electromagnetic waves. The present invention relates to an electromagnetic wave measuring apparatus for measuring electromagnetic waves.

  Conventionally, a transmission antenna that transmits radio waves and a reception antenna that receives transmitted radio waves are set in an electromagnetic wave measurement box formed of an internal hollow rectangular parallelepiped shape with a radio wave absorber on the inner surface. An electromagnetic wave measurement box for testing a receiving antenna by measuring the above has been proposed (see Patent Document 1).

The electromagnetic wave measurement box is configured to open a door portion that can be opened and closed on one side surface in the longitudinal direction and to install a receiving antenna on the bottom surface inside.
In this case, it is necessary to install the receiving antenna so that the inside of the small electromagnetic wave measurement box is looked into, and it is difficult to install the receiving antenna at a predetermined position with respect to the transmitting antenna.

  Therefore, it has been difficult to obtain highly reproducible measurement results in an electromagnetic wave measurement test in which the measurement results of the received electromagnetic waves are greatly affected by the relative position with respect to the transmitting antenna.

JP-A-10-93286

  In the electromagnetic wave measuring box having an electromagnetic wave absorber on the inner surface, a transmitter for transmitting an electromagnetic wave and a receiver for receiving the transmitted electromagnetic wave are separated from each other at a predetermined interval, and the other is positioned at a predetermined position. An object of the present invention is to provide an electromagnetic wave measuring apparatus that can be installed with good reproducibility.

In the present invention, a transmitter for transmitting electromagnetic waves and a receiver for receiving transmitted electromagnetic waves are installed at predetermined intervals inside an electromagnetic wave measurement box having an electromagnetic wave absorber on the inner surface, and the receiver receives the electromagnetic waves. An electromagnetic wave measuring apparatus for measuring electromagnetic waves, comprising at least one of the transmitting body and the receiving body as a test object, comprising an insertion means for allowing insertion of the test object to an installation position in the electromagnetic wave measurement box, The insertion means is configured to allow the DUT to be inserted in a direction orthogonal to a straight line connecting the transmitter and the receiver.
The direction orthogonal to the straight line connecting the transmitter and the receiver is, for example, a rectangular parallelepiped inside the electromagnetic wave measurement box, and is a predetermined interval direction between the transmitter and the receiver, that is, a straight line connecting the transmitter and the receiver. When the direction is the width direction, it includes a direction on a plane parallel to both side surfaces of the rectangular parallelepiped.

Thereby, by inserting this insertion means, the device under test can be easily installed at a predetermined position in a predetermined distance and direction within the electromagnetic wave measurement box with respect to the transmitter or the receiver. Therefore, variation in measurement results can be reduced, that is, measurement results with high reproducibility can be obtained.
In addition, for example, when the device under test is attached to the insertion means outside the electromagnetic wave measurement box, the device under test can be installed more easily. Accordingly, it is possible to reduce the time required for replacing the test object, and it is possible to reduce the entire test time even when testing a large number of test objects.

As an aspect of the present invention, a position where insertion is permitted by the insertion means can be formed on the bottom surface of the electromagnetic wave measurement box, and the insertion direction can be a vertically upward direction.
Thereby, for example, when the cable that transmits the electromagnetic wave received by the device under test to the measuring device is connected to the outer end of the device under test, the installation direction of the device under test is inclined by the weight of the cable, etc. It can be prevented from changing. Therefore, the device under test can be more easily installed at a predetermined position with respect to the transmitter or the receiver.

Further, as an aspect of the present invention, the insertion means includes an insertion hole formed in the bottom surface, and a moving body that moves through the insertion hole and moves the device under test to the installation position. In addition, a fitting member fitted to the bottom surface can be provided.
Thereby, an electromagnetic wave measurement box can be made into a substantially sealed state only by inserting a device under test into an installation position. Therefore, it is possible to prevent the electromagnetic wave transmitted from the transmission antenna from leaking from the insertion hole of the electromagnetic wave measurement box, and to further reduce the variation in the measurement result.

Further, as an aspect of the present invention, the movable body can be provided with a rotation allowing portion that allows the test object to rotate.
Thereby, for example, when the device under test is a directional antenna, it can be easily rotated in a desired direction, and an electromagnetic wave measurement result in this direction can be obtained.

Further, as an aspect of the present invention, the rotation axis direction of the rotation permission portion may be the same as the insertion direction.
Thus, for example, when testing a directional antenna as a device under test, the relative distance and direction with the other antenna can be maintained even if the device under test is rotated about the rotation axis. Therefore, even when the device under test is a directional antenna and is rotated, variation in measurement results can be further reduced.

  Further, as an aspect of the present invention, the receiver is the test object, and the receiver is composed of a composite receiver including a plurality of receivers having different frequencies of electromagnetic waves to be received. A receiving unit switching means for switching the receiving unit to be tested can be provided.

The composite receiver including a plurality of receiving units having different frequencies of the electromagnetic waves to be received is, for example, 1.5 GHz for GPS, 2.5 GHz for VICS, 5.8 GHz for ETC, and 800 MHz for mobile phones. It is a composite antenna provided integrally with an antenna that receives a plurality of types of frequencies.
The receiving unit switching means for switching the receiving unit to be tested switches a connection circuit connecting the receiving unit to be tested and a measuring device for measuring the received electromagnetic wave, for example, a single pole double throw contact (SPDT) or the like Including a changeover switch.

  As a result, the user can switch the receiving unit to be tested simply by switching the changeover switch, so that there is no need to connect and switch the receiving unit to be tested, and the composite receiver can be efficiently tested.

  In addition, for example, when a control device that controls switching of the changeover switch is provided, the user can switch the receiving unit that is the measurement target without physically touching the receiving unit, the receiver, and the changeover switch. Measurement results with higher reproducibility can be obtained without changing the measurement position of the receiving unit and the receiving body.

  According to the present invention, a transmitter for transmitting electromagnetic waves and a receiver for receiving transmitted electromagnetic waves can be easily installed in a predetermined distance and direction inside an electromagnetic wave measuring box having an electromagnetic wave absorber on the inner surface. It is possible to obtain electromagnetic wave measurement results with high reproducibility.

An embodiment of the present invention will be described below with reference to the drawings.
FIG. 1 showing a perspective view of the electromagnetic wave measuring device 1, FIG. 2 showing a plan sectional view of the electromagnetic wave measuring box 10, FIG. 3 showing a longitudinal sectional view near the center of the electromagnetic wave measuring device 1 in the measurement state, The electromagnetic wave measuring device 1 will be described together with FIG. 4 showing a longitudinal sectional view of the vicinity of the center of the electromagnetic wave measuring device 1 in the attached state.

The electromagnetic wave measuring apparatus 1 is formed in a form in which an electromagnetic wave measuring box 10 formed in a substantially rectangular parallelepiped shape and a substantially rectangular parallelepiped pedestal portion 20 having an open portion at the side surface and the center of the upper surface are stacked.
The pedestal portion 20 is formed in a substantially rectangular parallelepiped shape that is slightly larger than the electromagnetic wave measurement box 10 and has an appropriate height.

As shown in FIG. 2, the electromagnetic wave measuring box 10 has a two-layer structure in which a plurality of square pyramid-shaped electromagnetic wave absorbers 13 are arranged in an upright state inside a casing made of an iron plate 11. . Note that the size of the rectangular parallelepiped of the electromagnetic wave measurement box 10 may be an optimum size depending on the frequency of the electromagnetic wave to be measured, but this embodiment is intended for measurement in the frequency band of 1.4 GHz to 1.6 GHz. In the example, it is formed with a depth of about 70 cm, a height of about 70 cm, and a width of about 140 cm.
Moreover, the outer surface of the iron plate 11 is subjected to rust prevention treatment by appropriate coating. In addition, in the present Example, although the box is comprised with the iron plate 11, it is not limited to an iron plate, What is necessary is just a metal.

  The electromagnetic wave absorber 13 is configured by arranging a polyurethane foam in which a square-powder-shaped magnetic powder having an appropriate size according to the frequency of an electromagnetic wave to be tested is mixed, in a lattice shape. Thereby, the electromagnetic wave transmitted from the transmission antenna 32 described later can be prevented from being irregularly reflected inside the electromagnetic wave measurement box 10, and the reception antenna 31 can receive the direct wave transmitted from the transmission antenna 32.

  In the present embodiment, the electromagnetic wave absorber 13 uses a quadrangular pyramid-shaped body, but is not limited to this, and, for example, corners arranged in a staggered manner are chamfered according to the electromagnetic wave to be tested. Even if an electromagnetic wave absorber formed of a substantially quadrangular pyramid shape body, a conical shape body, a wedge shape body (a shape in which a triangular prism is laid down) continuously arranged in a line, or a sheet-like body is used. Good.

  In this embodiment, the electromagnetic wave absorber 13 is made of polyurethane foam in which a magnetic powder is blended. However, the electromagnetic wave absorber 13 is not limited to this, and depending on the electromagnetic wave to be tested, the magnetic powder An electromagnetic wave absorber formed of a blended epoxy resin material or a silicone resin material blended with magnetic powder may be used.

  In addition, a transmitting antenna 32 is mounted on the bottom surface 10a of the electromagnetic wave measuring box 10 at a point approximately ¼ from the left end in the width direction (left and right direction in FIG. 2) near the center in the depth direction (up and down direction in FIG. 2). And a receiving antenna mounting portion for mounting the receiving antenna 31 at a point substantially ¼ from the right end in the width direction.

  The transmitting antenna mounting portion includes a circular plate portion 14b fitted into a circular opening 14a provided in the bottom surface 10a, an electromagnetic wave absorber 13 provided on the upper surface of the circular plate portion 14b, and a connection connector 14c provided on the bottom surface side. It consists of In addition, the circular opening 14a is formed so that the bottom side portion is slightly larger in the radially outward direction. Thereby, the position of the transmission antenna 32 can be accurately attached.

  The circular plate portion 14b is formed of a cylindrical iron plate 11 provided with a flange projecting radially outward on the bottom surface side, and a column 32a of the transmission antenna 32 passes through the center in plan view, and is connected to the connection connector 14c. A connection hole that allows connection is provided.

  In the connection connector 14c, one end of a coaxial cable 41 whose upper end is fixed to the bottom surface side of the circular plate portion 14b and whose other end is connected to the transmission control unit is connected to the lower end side. Therefore, the coaxial cable 41 and the transmission antenna 32 can be electrically connected by physically connecting the support 32a of the transmission antenna 32 to the upper end side of the connection connector 14c.

  With the above configuration, the circular plate portion 14b in which the transmission antenna 32 is connected to the connection connector 14c is fixed in accordance with the circular opening 14a, so that the transmission control unit is electrically connected to the transmission antenna installation position 14 which is a desired position. A transmission antenna 32 can be installed.

The receiving antenna mounting portion is a fitting member, and a circular plate portion 15b fitted into a circular opening 15a provided in the bottom surface 10a, an electromagnetic wave absorber 13 provided on the top surface of the circular plate portion 15b, and a bottom surface side. The connection connector 15c is provided.
The circular plate portion 15b is formed of a cylindrical iron plate 11 having a thicker thickness than the bottom surface 10a, and a connection connector 15c connected to a connection connector 31b provided at the lower end of the support 31a of the reception antenna 31 is connected to the center in plan view. A connection through hole allowing penetration is provided. As shown in FIG. 4b, the side surface of the circular plate portion 15b is provided with a screw thread 15e that is screwed into a screw groove (not shown) provided on the inner surface of the circular opening 15a.

The connection connector 15c is supported by the circular plate portion 15b so that the vicinity of the upper end is substantially the same height as the upper surface of the circular plate portion 15b and is rotatable by a ball bearing 15d. Further, one end of a coaxial cable 42 whose other end is connected to the measuring device is connected to the lower end of the connection connector 15c.
Therefore, the coaxial cable 41 and the receiving antenna 31 can be rotated and electrically connected by screwing and connecting the connection connector 15c and the connection connector 31b with a screw thread and a screw groove (not shown). .

  With the above configuration, the circular plate portion 15b in which the lower end portion of the column 31a is connected to the connection connector 15c is screwed into the circular opening 15a, so that the receiving antenna installation position 15 which is a desired position is electrically connected to the measurement apparatus. A connected receiving antenna 31 can be installed.

  Therefore, the user can install the reception antenna 31 in the electromagnetic wave measurement box 10 at the reception antenna installation position 15 that is a predetermined distance and direction with respect to the transmission antenna 31. Further, the user transmits the electromagnetic wave to the transmission antenna 32 by the transmission control unit via the coaxial cable 41 and measures the signal of the reception electromagnetic wave from the reception antenna 31 that has received the transmitted electromagnetic wave via the coaxial cable 42. The test of the receiving antenna 31 can be executed by measuring the reception electromagnetic wave of the receiving antenna 31 received by the apparatus.

  More specifically, the receiving antenna 31 is screwed in a vertical direction perpendicular to the bottom surface 10a by the circular plate portion 15b, and the receiving antenna 31 and the transmitting antenna 32 are installed on the bottom surface 10a on the same plane. Therefore, the reception antenna 31 can be easily installed at the reception antenna installation position 15 that is a predetermined distance and direction with respect to the transmission antenna 32.

  In other words, since the direction connecting the transmission antenna installation position 14 and the reception antenna installation position 15 is the same as the width direction of the electromagnetic wave measurement box 10, the reception antenna installation position 15 is parallel to the front and back surfaces of the electromagnetic wave measurement box 10. The circular plate portion 15b can be screwed into the in-plane direction of the passing vertical surface. Therefore, the receiving antenna 31 can be installed at a predetermined distance and direction with respect to the transmitting antenna 32. Further, since the receiving antenna 31 is mounted at the center of the circular plate portion 15b, the receiving antenna 31 can be installed at the receiving antenna installation position 15 without changing the relative distance to the transmitting antenna 32.

  Since the circular plate portion 15b is formed to be thicker than the thickness of the bottom surface 10a, the user can easily hold the circular plate portion 15b into the circular opening 15a by gripping a portion protruding downward from the bottom surface 10a. Can be screwed in. In the electromagnetic wave measuring box 10 of the present embodiment where the receiving antenna 31 is frequently attached and detached, this configuration is preferable because it can be easily screwed. In addition, as long as attachment and removal of the receiving antenna 31 are easy, forms other than the said form may be sufficient.

  Further, even when a plurality of receiving antennas 31 are continuously tested, the circular plate portion 15b is removed from the electromagnetic wave measuring box 10 together with the receiving antenna 31 by removing the circular plate portion 15b from the circular opening 15a, and is removed from the electromagnetic wave measuring box 10. The receiving antenna 31 of the circular plate portion 15b can be replaced and set again at the receiving antenna installation position 15.

  Therefore, the user can perform an exchange operation that can install the reception antenna 31 at the reception antenna installation position 15 that is a predetermined distance and direction with respect to the transmission antenna 32 by the easy operation as described above. Therefore, when many receiving antennas 31 are tested by an easy replacement operation, the time required for replacement can be shortened.

  Furthermore, the electromagnetic wave measurement box 10 can be substantially sealed by attaching the circular plate portion 15b and the circular plate portion 14b to the circular opening 15a and the circular opening 14a, respectively. Therefore, compared to the case of closing the circular opening 14a or the circular opening 15a with another member, the electromagnetic wave measuring box 10 can be substantially sealed only by the operation of installing the receiving antenna 31 and the transmitting antenna 32, so that the work efficiency is improved. User convenience is improved.

  Further, by providing the electromagnetic wave absorber 13 on the upper surface of the circular plate portion 15b and the circular plate portion 14b, the irregular reflection of the electromagnetic wave transmitted from the transmitting antenna 32 can be prevented, and only the direct wave transmitted by the transmitting antenna 32 is received. The antenna 31 can receive. Therefore, variation in measurement results can be further reduced, that is, measurement results with higher reproducibility can be obtained.

  As shown in FIGS. 3 and 4, the support 31 a of the receiving antenna 31 and the support 32 a of the transmitting antenna 32 are formed of hollow cylindrical pipes, and the antenna cables for the receiving antenna 31 and the transmitting antenna 32 are provided inside. Since (not shown) is inserted, irregular reflection of the electromagnetic wave transmitted from the transmission antenna 32 can be prevented, and the reception antenna 31 can receive only the direct wave transmitted by the transmission antenna 32. Therefore, variation in measurement results can be further reduced, that is, measurement results with higher reproducibility can be obtained.

  Furthermore, the support 31a and the support 32a are made of polyacetal resin having a dielectric constant close to that of air. Thereby, the influence on the reception of electromagnetic waves by the column 31a and the column 32a can be reduced, and measurement results with smaller variations can be obtained. In addition, the support | pillar 31a and the support | pillar 32a are not limited to the said polyacetal resin, For example, the dielectric constants, such as a fluororesin, should just be formed with the material close | similar to the dielectric constant of air.

  In addition, you may attach the electromagnetic wave absorber 13 to the outer periphery of the support | pillar 31a of the receiving antenna 31, and the support | pillar 32a of the transmission antenna 32. FIG. Thereby, the irregular reflection of the electromagnetic wave transmitted from the transmission antenna 32 can be further prevented, and only the direct wave transmitted by the transmission antenna 32 can be received by the reception antenna 31. Therefore, it is possible to obtain a measurement result with a small variation.

  Moreover, since the receiving antenna 31 is connected to the connection connector 15c fixed so as to be rotatable with respect to the circular plate portion 15b, the receiving antenna 31 having directivity can be tested. In this case, as shown in FIG. 5 which is an enlarged bottom view of the circular plate portion 15b, a directional arrow 16 is provided on the outer surface of the portion protruding downward from the bottom surface 10a of the connection connector 15c, and the circular plate portion 15b A rotation direction scale 17 may be provided on the bottom surface.

  When the user connects the column 31a to the connection connector 15c, the user connects the direction of the direction arrow 16 and the direction of the reception antenna 31 in the same direction, so that the reception antenna installed at the reception antenna installation position 15 The installation direction of 31 can be confirmed from the outside of the electromagnetic wave measurement box 10.

  Accordingly, the user can set the installation direction of the reception antenna 31 installed at the reception antenna installation position 15 inside the electromagnetic wave measurement box 10 from the outside of the electromagnetic wave measurement box 10 by the scale of the rotation direction scale 17 indicated by the direction arrow 16. Since it can be confirmed, it is possible to easily test the receiving antenna 31 having directivity.

  In addition, without providing the directional arrow 16 and the rotation direction scale 17, a rotation drive device such as a motor and a rotary encoder are provided on the circular plate portion 15b to mechanically read the installation direction of the reception antenna 31. Also good.

Further, the circular opening 14a and the circular plate portion 14b in which the transmission antenna 32 is installed may be configured similarly to the circular opening 15a and the circular plate portion 15b. Thereby, like the receiving antenna 31 in the present embodiment, the transmitting antenna 32 can be easily installed at an installation position having a predetermined distance and direction with respect to the receiving antenna 31.
In the above test, the receiving antenna 31 is used as a device under test, but the transmitting antenna 32 can be used as a device under test.

  Further, in this embodiment, the receiving antenna 31 as the device under test is installed at the receiving antenna installation position 15 by screwing the circular plate portion 15b into the circular opening 15a, but is movable in the vertical direction with respect to the circular opening 15a. The structure which makes the circular plate part 15b fit to the circular opening 15a by the drive device to perform may be sufficient.

  Further, a connection connector may be provided at each of the upper end of the support 31a and the lower end of the reception antenna 31, and the reception antenna 31 may be configured to be removable from the support 31a by the connection connector. With this configuration, by exchanging only the receiving antenna 31, it is possible to easily replace the plurality of receiving antennas 31 and execute the test.

  Further, each of the circular opening 15a and the circular plate portion 15b may be formed in a truncated cone shape with a small diameter on the upper side, and a thread or a thread groove may be formed in each. With this configuration, when the circular plate portion 15b is screwed into the circular opening 15a, the circular plate portion 15b is screwed into the wedge-shaped circular opening 15a, so that the screw to the bottom surface 10a of the electromagnetic wave measurement box 10 is screwed. The height of the circular plate portion 15b after completion of the combination can be made constant. Therefore, the receiving antenna 31 can be more easily installed at a predetermined height.

  Further, as shown in FIG. 6, the electromagnetic wave measuring apparatus 1 may be configured to test a composite antenna 50 instead of the receiving antenna 31 of the above embodiment. In this case, a switching SW 60 is provided between the composite antenna 50 and the connection connector 15c.

  The composite antenna 50 includes an antenna body 51a for 1.5 GHz used for GPS, an antenna body 51b for 5.8 GHz used for ETC, and an antenna body 51c for 2.5 GHz used for VICS, Four antenna bodies 51d for 800 MHz used for cellular phones are provided, and each antenna body 51 (51a, 51b, 51c, 51d) has a connection wiring 52 (52a, 52b, 52c, 52d). One end is connected.

  The switching SW 60 is configured by combining three high-frequency SPDTs 61 (61a, 61b, 61c) that are single-pole double-throw contacts. Each high-frequency SPDT 61 has two input contacts 62a and 62b on the input side and one output contact 62c on the output side, and a control device (not shown) is connected to connect connections 62a-62c and connections 62b-62c. It is the structure to switch.

  The other end of the connection wiring 52d connected to the antenna body 51d is connected to the input contact 62a of the high frequency SPDT 61a, and the other end of the connection wiring 52c connected to the antenna body 51c is connected to the input contact 62b of the high frequency SPDT 61a. The other end of the connection wiring 52b connected to the antenna body 51b is connected to the input contact 62a of the high frequency SPDT 61b, and the other end of the connection wiring 52a connected to the antenna body 51a is connected to the input contact 62b of the high frequency SPDT 61b. Has been.

  The output contact 62c of the high frequency SPDT 61a is connected to the input contact 62a of the high frequency SPDT 61c, the output contact 62c of the high frequency SPDT 61b is connected to the input contact 62b of the high frequency SPDT 61c, and the output contact 62c of the high frequency SPDT 61c is rotated by the ball bearing 15d. While being supported by the circular plate portion 15 b so as to be movable, the other end is connected to a connection connector 15 c connected to the coaxial cable 42.

  In the other configuration of the electromagnetic wave measuring apparatus 1, the transmission antenna 32 that transmits electromagnetic waves toward the composite antenna 50 is a transmission antenna that can transmit electromagnetic waves of a plurality of types of frequencies received by the antenna body 51. The measurement box 10 is the same as the electromagnetic wave measurement apparatus 1 of the above-described embodiment for testing the reception antenna 31 except that the measurement box 10 is composed of an electromagnetic wave absorber 13 and a size suitable for electromagnetic waves of those frequencies.

  With the above configuration, when testing the composite antenna 50 including four antenna bodies 51 that receive different frequencies, the wiring connection of the connection wiring 52 connected to the antenna body 51 to be tested to the connection connector 15c is performed. The antenna body 51 can be measured by operating the control device (not shown) and switching the switching SW 60 without switching the attachment / detachment. Therefore, it is possible to reduce wiring connection labor when testing the composite antenna 50 having the plurality of antenna bodies 51, and the composite antenna 50 can be tested efficiently and in a short time.

  In addition, it is necessary to temporarily switch the connection of the connection wiring 52 to the connection connector 15c by taking out the circular plate portion 15b. However, since the connection can be switched by the switching SW 60, the test can be efficiently performed in a short time. In addition, the test can be performed without changing the receiving antenna installation position of the composite antenna 50, and a test with further improved reproducibility can be realized.

  Further, by arranging the switching SW 60 between the composite antenna 50 and the connection connector 15 c, the composite antenna 50 and the coaxial cable 42 can be pivotably connected via the connection connector 15 c and connected to the antenna body 51. Compared with the case where the plurality of wirings straddling the rotating portion, the test is prevented from being a test in which reproducibility is reduced due to a change in characteristics such as conductivity of the wiring itself due to the twisting of the wiring. That is, a plurality of connection wirings 52 can be connected to the coaxial cable 42 via the switching SW 60 without straddling the rotating portion, thereby realizing a highly reproducible and stable test.

  Note that the frequency received by the antenna body 51 and the number of antenna bodies 51 provided in the composite antenna 50 are not limited to the above frequency and number. For example, 1.5 GHz, 1.7 GHz or An antenna body 51 that receives 2.0 GHz may be provided, and the composite antenna 50 may be configured with four or more antenna bodies 51.

In correspondence between the configuration of the present invention and the above-described embodiment,
The transmitter of the present invention corresponds to the transmission antenna 32,
Similarly,
The receiver corresponds to the receiving antenna 31,
The installation position corresponds to the receiving antenna installation position 15,
The insertion means corresponds to the circular opening 15a and the circular plate portion 15b,
The mounting position corresponds to the insertion hole 15f,
The insertion hole corresponds to the circular opening 15a,
The fitting member corresponds to the circular plate portion 15b,
The rotation permission portion corresponds to the connection connector 15c and the ball bearing 15d,
The receiver corresponds to the antenna body 51,
The composite receiver corresponds to the composite antenna 50,
The receiving unit switching means corresponds to the switching SW 60 and the high frequency SPDT 61,
The present invention is not limited only to the configuration of the above-described embodiment, and many embodiments can be obtained.

The perspective view of an electromagnetic wave measuring device. The plane sectional view of an electromagnetic wave measurement box. The longitudinal cross-sectional view near the center of the electromagnetic wave measuring apparatus of a measurement state. The longitudinal cross-sectional view near the center of the electromagnetic wave measuring apparatus of the attachment state of a receiving antenna. The enlarged bottom view of a receiving antenna mounting part. Explanatory drawing explaining the outline | summary about a composite antenna and switching SW.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Electromagnetic wave measuring apparatus 10 ... Electromagnetic wave measuring box 10a ... Bottom surface 13 ... Electromagnetic wave absorber 15 ... Reception antenna installation position 15a ... Circular opening 15b ... Circular plate part 15c ... Connection connector 15d ... Ball bearing 15f ... Insertion hole 31 ... Reception antenna 32 ... Transmitting antenna 50 ... Compound antenna 51 ... Antenna body 60 ... Switching SW
61 ... High-frequency SPDT

Claims (6)

A transmitter for transmitting electromagnetic waves and a receiver for receiving transmitted electromagnetic waves are installed at predetermined intervals inside an electromagnetic wave measuring box having an electromagnetic wave absorber on the inner surface, and the electromagnetic waves received by the receiver are measured. An electromagnetic wave measuring device,
At least one of the transmitter and the receiver is a device under test,
An insertion means for allowing insertion of the device under test up to an installation position in the electromagnetic wave measurement box;
An electromagnetic wave measuring apparatus in which the insertion means is configured to permit insertion of the device under test in a direction orthogonal to a straight line connecting the transmitter and the receiver. The insertion allowing position by the insertion means is configured on the bottom surface of the electromagnetic wave measurement box,
The electromagnetic wave measuring apparatus according to claim 1, wherein the insertion direction is a vertically upward direction. The insertion means;
An insertion hole formed in the bottom surface and a moving body that passes through the insertion hole and moves the device under test to the installation position,
The electromagnetic wave measuring apparatus according to claim 2, wherein the movable body includes a fitting member that fits on the bottom surface. The electromagnetic wave measuring apparatus according to claim 3, wherein the movable body is provided with a rotation permission portion that allows the test object to rotate. The rotation axis direction of the rotation allowing portion is
The electromagnetic wave measuring apparatus according to claim 4, wherein the electromagnetic wave measuring apparatus is in the same direction as the insertion direction. The receiver is the device under test,
The receiver is composed of a composite receiver including a plurality of receiving units having different frequencies of electromagnetic waves to be received,
In the moving body,
The electromagnetic wave measuring device according to claim 3, 4, or 5, further comprising a receiving unit switching unit that switches the receiving unit to be tested.

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