JP2003344469A - Electromagnetic wave measuring instrument and electromagnetic wave measuring method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To highly accurately measure electromagnetic wave to be measured. <P>SOLUTION: An electromagnetic wave measuring instrument for measuring electromagnetic wave to be measured which is transmitted by a measured object is equipped with a measurement antenna for receiving the electromagnetic wave to be measured, a reference antenna for transmitting or receiving reference electromagnetic wave having a known polarization direction, a rotary hold part for holding the measurement antenna rotatably relative to the reference antenna, and a measurement part for measuring the intensity of the reference electromagnetic wave transmitted by the reference antenna and received by the measurement antenna or the intensity of the reference electromagnetic wave transmitted by the measurement antenna and received by the reference antenna. <P>COPYRIGHT: (C)2004,JPO

Description

Detailed Description of the Invention

[0001]

TECHNICAL FIELD The present invention relates to an electromagnetic wave measuring device and an electromagnetic wave measuring method. In particular, the present invention relates to an electromagnetic wave measuring device including a scanning mechanism section that scans a measurement antenna with respect to an object to be measured.

[0002]

2. Description of the Related Art Conventionally, a method of measuring an electromagnetic wave transmitted by an object to be measured using a probe antenna has been known. In the above measurement, the polarization direction of the probe antenna is adjusted in advance in the horizontal direction or the vertical direction by using, for example, a level.

[0003]

However, when a minute probe antenna is used for measurement, it is difficult to adjust the polarization direction with high accuracy by visual inspection using a level. Therefore, an error may occur in the measurement value due to the deviation of the polarization direction, and it has been difficult to perform electromagnetic wave measurement with high accuracy.

Therefore, an object of the present invention is to provide an electromagnetic wave measuring device and an electromagnetic wave measuring method which can solve the above problems. This object is achieved by a combination of features described in independent claims of the invention. The dependent claims define further advantageous specific examples of the present invention.

[0005]

That is, according to a first aspect of the present invention, an electromagnetic wave measuring device for measuring an electromagnetic wave to be measured transmitted by an object to be measured, comprising a measuring antenna for receiving the electromagnetic wave to be measured, A reference antenna that transmits or receives a reference electromagnetic wave having a known polarization direction, a rotation holding unit that holds the measurement antenna rotatably with respect to the reference antenna, and a strength at which the measurement antenna receives the reference electromagnetic wave transmitted by the reference antenna. Or a measuring unit for measuring the intensity of the reference antenna receiving the reference electromagnetic wave transmitted by the measurement antenna.

Further, an anechoic chamber may be further provided, and the measurement antenna and the reference antenna may be placed in the anechoic chamber. A scanning mechanism unit for scanning the measurement antenna with respect to the DUT may be further provided. The reference antenna preferably transmits or receives a linearly polarized reference electromagnetic wave.

The reference antenna may be a radio wave transmission path for transmitting a quasi-transverse electromagnetic field wave. The reference antenna may be a microstrip line. The ends of the microstrip lines may be misaligned. The measurement antenna may be a shielded loop antenna.

Further, a rotation driving unit for rotating the measurement antenna with respect to the reference antenna may be further provided. The rotation drive unit may change the polarization direction of the measurement antenna by rotating the measurement antenna. The rotation driving unit may rotate the measurement antenna based on the intensity measured by the measurement unit or the reference antenna receives the reference electromagnetic wave. The rotation driving unit may rotate the measurement antenna to direct the polarization direction of the measurement antenna to the direction in which the received intensity is maximum or minimum. Further, the reference antenna may be detachably held, and instead of the reference antenna, a fixing portion to which an object to be measured can be attached may be further provided.

According to a second aspect of the present invention, there is provided an electromagnetic wave measuring instrument for measuring an electromagnetic wave transmitted by an object to be measured in an anechoic chamber, wherein the reference is placed in the anechoic chamber and has a known polarization direction. It has a reference antenna for transmitting or receiving electromagnetic waves.

According to a third aspect of the present invention, there is provided an electromagnetic wave measuring method for measuring an electromagnetic wave to be measured transmitted by an object to be measured, wherein the reference antenna transmits or receives a reference electromagnetic wave having a known polarization direction. A reference electromagnetic wave transmission / reception step, a rotation step of rotating the measurement antenna with respect to the reference antenna, and a measurement step of causing the measurement antenna to measure the electromagnetic wave to be measured. Further, a step of attaching the object to be measured may be further provided, in which the reference antenna is removed from the fixing portion for fixing the reference antenna, and the object to be measured is attached to the fixing portion instead.

According to a fourth aspect of the present invention, there is provided an electromagnetic wave measuring method for measuring an electromagnetic wave transmitted by an object to be measured in an anechoic chamber, wherein a known polarization is applied to a reference antenna placed in the anechoic chamber. A reference electromagnetic wave transmitting / receiving step of transmitting or receiving a reference electromagnetic wave having a direction is provided.

The above summary of the invention does not enumerate all the necessary features of the present invention, and sub-combinations of these feature groups can also be the invention.

[0013]

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, the present invention will be described through embodiments of the invention, but the following embodiments do not limit the claimed invention, and the features described in the embodiments Not all combinations are essential to the solution of the invention.

FIG. 1 shows an electromagnetic wave measuring device 100 according to an example of an embodiment of the present invention. The electromagnetic wave measuring device 100 includes a measurement antenna 102, which is a probe antenna, and an object to be measured 11
6 is a scanning antenna system that scans 6 to measure an electromagnetic wave to be measured transmitted by the object 116 to be measured. The electromagnetic wave measurement device 100 includes an anechoic chamber 110, a fixed part 118, a measurement antenna 102, a measurement part 108, a rotation holding part 106, and a scanning mechanism part 112.

The anechoic chamber 110 has an electromagnetic wave absorber 2 on its inner wall.
08, which has a DUT 116 and a measurement antenna 1 in the room.
Place 02. The fixing portion 118 fixes the DUT 116. The measurement antenna 102 receives the electromagnetic wave under measurement transmitted by the DUT 116. The measurement unit 108 is electrically connected to the measurement antenna 102 via the cable 206, and measures the intensity with which the measurement antenna 102 receives the electromagnetic wave to be measured. The rotation holding unit 106 holds the measurement antenna 102 rotatably, and the scanning mechanism unit 112 causes the DUT 116 to scan the measurement antenna 102.

In the present embodiment, the scanning mechanism section 112.
Scans the measurement antenna 102 with respect to a Cartesian coordinate system including a Z-axis having a horizontal direction from the measurement antenna 102 toward the DUT 116, a vertically upward Y-axis, and an X-axis orthogonal to the Y-axis and the Z-axis. To do. In another embodiment, the scanning mechanism unit 112 may scan the measurement antenna 102 with respect to a cylindrical coordinate system or a spherical coordinate system (polar coordinate system).

Further, in the present embodiment, the object to be measured 11 is
The horn antenna, which is an example of No. 6, is electrically connected to the oscillator 202 via the cable 204 and transmits the electromagnetic wave to be measured based on the signal output from the oscillator 202. In another example, the device under test 116 may receive the electromagnetic wave under test transmitted by the measurement antenna. In this case, the measurement antenna 102 is electrically connected to the oscillator 202, and the DUT 116 is electrically connected to the measurement unit 108.

FIG. 2 shows an example of a detailed configuration of the measurement antenna 102 and the rotation holding unit 106. In the present embodiment, the measurement antenna 102 is a shielded loop antenna, which is an example of a magnetic field antenna, and detects a magnetic field change in a direction perpendicular to the loop surface. Therefore, the measurement antenna 102 has a function of receiving an electromagnetic wave traveling in the direction within the loop plane. In another embodiment, the measurement antenna 1
02 may be an electric field antenna.

The rotation holding unit 106 has a measuring antenna 102.
Are rotatably held with respect to the rotation axis in the Z-axis direction (see FIG. 1). In this case, the rotation holding unit 106 holds the loop surface of the measurement antenna 102 parallel to the Z axis.

Further, the rotation holding unit 106 has a rotation driving unit 114 for rotating the measurement antenna 102. The rotation driving unit 114 changes the orientation of the loop surface of the measurement antenna 102 by rotating the measurement antenna 102 with respect to the rotation axis. As a result, the rotation driving unit 114
The polarization direction of the measurement antenna 102 is changed.

Further, the rotation driving unit 114 includes a measuring unit 108.
The measurement antenna 102 is rotated in response to the control signal received from. The measurement unit 108 outputs a control signal according to the intensity with which the measurement antenna 102 receives an electromagnetic wave. Thereby, the polarization direction of the measurement antenna 102 can be changed by feedback control according to the reception intensity. In the present embodiment, the measurement antenna 102 receives a reference electromagnetic wave having a known polarization direction, and the polarization direction of the measurement antenna 102 is adjusted based on the intensity of the reception.

FIG. 3 shows a microstrip line 104 which is an example of a reference antenna for transmitting a reference electromagnetic wave. The microstrip line 104 includes the dielectric plate 41.
2, a back surface conductor 404, and a front surface conductor 402. The dielectric plate 412 has a rectangular parallelepiped shape. Back conductor 404
Is a grounded conductor that covers the entire back surface of the dielectric plate 412. The surface conductor 402 is a conductor formed on a part of the surface of the dielectric plate 412 in parallel with the sides of the dielectric plate 412 and across the surface of the dielectric plate 412.

When transmitting the reference electromagnetic wave, the surface conductor 40
One end of 2 is electrically connected to the oscillator 202 via the connector 408 and the cable 410. In addition, the microstrip line 10 which is the other end of the surface conductor 402
The four ends are mismatched terminated by the termination connector 406. In this case, the microstrip line 104
Produces a standing wave with a current antinode, which is the current maximum. As a result, the microstrip line 104 is
An electromagnetic field having a larger magnetic field component than the electric field component is generated in the vicinity.

Here, the terminal connector 406 is, for example,
It may be a short circuit connector or an open connector. The short circuit connector may be a connector that grounds the end of the surface conductor 402 through a predetermined impedance.

Further, the microstrip line 104
Preferably transmits a reference electromagnetic wave having a wavelength sufficiently long with respect to the size of the measurement antenna 102 (see FIG. 1). In this case, the microstrip line 104 generates a standing wave that generates a wide electromagnetic field in a region where the magnetic field component is large, so that the polarization direction of the measurement antenna 102 can be adjusted more accurately. According to this embodiment, the measurement antenna 1
A reference electromagnetic wave suitable for adjusting the polarization direction of 02 can be transmitted.

In another embodiment, the reference antenna may be an antenna having a known characteristic, for example, a horn antenna or a dipole antenna. Further, the reference antenna may be a transmission line having a known characteristic, for example, a quasi-transverse electromagnetic field wave (quasi-TEM).
It may be a radio wave transmission path for transmitting waves. The reference antenna preferably transmits a linearly polarized reference electromagnetic wave.

FIG. 4 shows an example of the configuration of the electromagnetic wave measuring device 100 when the polarization direction of the measurement antenna 102 is adjusted (hereinafter referred to as adjustment). In the present embodiment, the microstrip line 104 is placed on the fixing portion 118 that fixes the DUT 116 when the measurement antenna 102 receives the measurement electromagnetic wave (hereinafter, referred to as measurement time).

In this case, at the time of measurement, the microstrip line 104 is removed from the fixed portion 118, and the DUT 1 is measured.
16 is instead attached to the fixed part 118. Thereby, the polarization direction of the measurement antenna 102 can be adjusted under the condition close to the time of measurement. In another embodiment, the microstrip line 104 includes the device under test 11
It may be fixed at a position different from 6.

In the present embodiment, the microstrip line 104 is fixed by the reference antenna supporting portion 414 placed on the fixing portion 118 so that the surface on which the surface conductor 402 is provided faces the measurement antenna 102. It In this case, on the surface of the microstrip line 104, the rotation driving unit 114 (see FIG. 2) has the measurement antenna 102.
Is preferably perpendicular to the axis of rotation about which is rotated. Also,
The surface conductor 402 horizontally traverses the surface of the microstrip line 104. Accordingly, the microstrip line 104 can transmit the reference electromagnetic wave having the known polarization direction. In another example, the microstrip line 104 may traverse the surface vertically.

Here, at the time of adjustment, the rotation holding portion 10
6 holds the measurement antenna 102 rotatably with respect to the microstrip line 104. Further, the microstrip line 104 transmits the reference electromagnetic wave, and the measurement antenna 102 receives the reference electromagnetic wave. Then, the measurement unit 108 measures the intensity of reception of the reference electromagnetic wave, and the rotation driving unit 114 rotates the measurement antenna 102 with respect to the microstrip line 104 based on the measured intensity of reception.

In this case, the rotation driving unit 114 may turn the polarization direction of the measurement antenna 102 in the direction in which the intensity of reception of the reference electromagnetic wave becomes maximum or minimum. According to this embodiment, the polarization direction of the measurement antenna 102 can be adjusted to a desired direction by rotating the measurement antenna 102 based on the intensity of receiving the reference electromagnetic wave whose polarization plane is known.

Further, at the time of adjustment, the scanning mechanism section 112
(See FIG. 1) drives the measurement antenna 102 so that the tip of the measurement antenna 102 is moved to the microstrip line 10.
Hold near 4. The scanning mechanism section 112 preferably arranges the tip of the measurement antenna 102 near the current antinode of the standing wave generated in the microstrip line 104. In this case, the measurement antenna 102 can efficiently receive the reference electromagnetic wave transmitted by the microstrip line 104.

FIG. 5 is a flowchart showing an example of an electromagnetic wave measuring method according to the electromagnetic wave measuring device 100. The electromagnetic wave measuring method of the present embodiment includes a reference electromagnetic wave transmitting / receiving step S10.
2, a rotation step S104, an object mounting step S106, and a measurement step S108.

In the electromagnetic wave measuring method, first, in a reference electromagnetic wave transmitting / receiving step S102, a reference electromagnetic wave having a known polarization direction is transmitted to a microstrip line 104 placed in an anechoic chamber, and the measuring antenna 102 is used as a reference. Receive electromagnetic waves. Then, next, the rotation step S104
In, the rotation driving unit 114 rotates the measurement antenna 102 with respect to the microstrip line 104, and adjusts the polarization direction of the measurement antenna 102 to a desired direction.

Next, in the object mounting step S106, the microstrip line 104 is removed from the fixing portion 118 for fixing the microstrip line 104, and the object 116 to be measured is attached to the fixing portion 118 instead. Then, in the measuring step S108, the device under test 11
6, the electromagnetic wave to be measured is transmitted to the measurement antenna 102,
The measured electromagnetic wave is measured.

Here, in another embodiment, in the reference electromagnetic wave transmitting / receiving step S102, the measuring antenna 102 may transmit the reference electromagnetic wave and the microstrip line 104 may receive the reference electromagnetic wave. In this case, the measurement antenna 10
2 is electrically connected to the oscillator 202, and the microstrip line 104 is electrically connected to the measuring unit 108. The measuring unit 108 is the microstrip line 104.
Measures the strength of receiving the reference electromagnetic wave. Then, in the rotation step S104, the rotation driving unit 114 rotates the measurement antenna 102 based on the intensity of the reception.

Further, in the rotating step S104, the operator may rotate the measuring antenna 102 based on the measurement result of the measuring section 108. In this case, the operator may directly touch the measurement antenna 102 to rotate the measurement antenna 102, or may operate the rotation drive unit 114 to rotate the measurement antenna 102 by the rotation drive unit 114.
In this case, the measurement unit 108 preferably has a display unit that displays the measurement result. The measurement unit 108 may display the angle at which the measurement antenna 102 should be rotated on the display unit.

In yet another embodiment, the rotating step S1
At 04, the microstrip line 104 may be rotated relative to the measurement antenna 102. in this case,
The measuring unit 108 is, for example, the microstrip line 1
Based on the angle by which 04 is rotated, the measurement antenna 102
The correction amount for the measurement result may be calculated.

According to this embodiment, the polarization direction of the measurement antenna 102 can be adjusted with high accuracy, and the electromagnetic wave to be measured can be measured with high accuracy.

Although the present invention has been described with reference to the embodiments, the technical scope of the present invention is not limited to the scope described in the above embodiments. Various changes or improvements can be added to the above-described embodiment. It is also possible to include such modifications or improvements in the technical scope of the present invention.
It is clear from the description of the claims.

[0041]

As is apparent from the above description, according to the present invention, the electromagnetic wave to be measured can be measured with high accuracy.

[Brief description of drawings]

FIG. 1 is a diagram showing an electromagnetic wave measuring device 100 according to an example of an embodiment of the present invention.

FIG. 2 is a diagram showing an example of a detailed configuration of a measurement antenna 102 and a rotation holding unit 106.

FIG. 3 is a diagram showing a microstrip line 104.

FIG. 4 is a diagram showing an example of a configuration of an electromagnetic wave measuring device 100 at the time of adjustment.

5 is a flowchart showing an example of an electromagnetic wave measuring method according to the electromagnetic wave measuring device 100. FIG.

[Explanation of symbols]

100 ... Electromagnetic wave measuring device, 102 ... Measuring antenna, 104 ... Microstrip line, 106 ...
..Rotary holding unit, 108 ... Measuring unit, 110 ... Anechoic chamber, 112 ... Scanning mechanism unit, 114 ... Rotation drive unit, 116 ... Object to be measured, 118 ... Fixed unit Two
02 ... Oscillator, 204 ... Cable, 206 ...
・ Cable, 208 ... Electromagnetic wave absorber, 402 ...
Front surface conductor, 404 ... Back surface conductor, 406 ... Termination connector, 408 ... Connection connector, 410 ... Cable, 412 ... Dielectric plate, 414 ... Reference antenna support portion

Claims (17)

[Claims] 1. An electromagnetic wave measuring device for measuring an electromagnetic wave to be measured transmitted by an object to be measured, comprising: a measuring antenna for receiving the electromagnetic wave to be measured; and a reference for transmitting or receiving a reference electromagnetic wave having a known polarization direction. An antenna, a rotation holding unit that holds the measurement antenna rotatably with respect to the reference antenna, an intensity at which the measurement antenna receives the reference electromagnetic wave transmitted by the reference antenna, or the reference transmitted by the measurement antenna. An electromagnetic wave measuring instrument, comprising: a measuring unit for measuring the intensity of the electromagnetic wave received by the reference antenna. 2. The electromagnetic wave measuring device according to claim 1, further comprising an anechoic chamber, wherein the measurement antenna and the reference antenna are placed in the anechoic chamber. 3. The electromagnetic wave measuring instrument according to claim 1, further comprising a scanning mechanism section that scans the measurement antenna with respect to the object to be measured. 4. The reference antenna transmits or receives the linearly polarized reference electromagnetic wave.
Electromagnetic wave measurement device described in. 5. The electromagnetic wave measuring device according to claim 1, wherein the reference antenna is a radio wave transmission line that transmits a quasi-transverse electromagnetic field wave. 6. The electromagnetic wave measuring device according to claim 1, wherein the reference antenna is a microstrip line. 7. The electromagnetic wave measuring device according to claim 6, wherein the ends of the microstrip line are mismatched. 8. The electromagnetic wave measuring device according to claim 1, wherein the measuring antenna is a shielded loop antenna. 9. The electromagnetic wave measuring device according to claim 1, further comprising a rotation driving unit that rotates the measurement antenna with respect to the reference antenna. 10. The electromagnetic wave measuring device according to claim 9, wherein the rotation drive unit changes the polarization direction of the measurement antenna by rotating the measurement antenna. 11. The rotation driving unit rotates the measurement antenna based on the intensity measured by the measurement unit and received by the measurement antenna or the reference antenna. 10. The electromagnetic wave measuring device according to 10. 12. The rotation drive unit rotates the measurement antenna to direct the polarization direction of the measurement antenna to the direction in which the received intensity is maximum or minimum. Electromagnetic wave measurement device described in. 13. The electromagnetic wave measuring instrument according to claim 1, further comprising a fixing portion that detachably holds the reference antenna and replaces the reference antenna, and to which the object to be measured can be attached. 14. An electromagnetic wave measuring device for measuring an electromagnetic wave transmitted by an object to be measured in an anechoic chamber, which is a reference placed in the anechoic chamber and transmitting or receiving a reference electromagnetic wave having a known polarization direction. An electromagnetic wave measuring instrument comprising an antenna. 15. An electromagnetic wave measuring method for measuring an electromagnetic wave to be measured transmitted by an object to be measured, comprising: a reference electromagnetic wave transmitting / receiving step of transmitting or receiving a reference electromagnetic wave having a known polarization direction to a reference antenna; and a measuring antenna. An electromagnetic wave measuring method comprising: a rotating step of rotating the electromagnetic wave with respect to the reference antenna; and a measuring step of causing the measuring antenna to measure the electromagnetic wave to be measured. 16. The method according to claim 15, further comprising the step of attaching the DUT to the fixed portion for fixing the reference antenna, and removing the reference antenna from the fixed portion, and attaching the DUT to the fixed portion instead. Electromagnetic wave measurement method. 17. A method of measuring an electromagnetic wave transmitted by an object to be measured in an anechoic chamber, comprising transmitting a reference electromagnetic wave having a known polarization direction to a reference antenna placed in the anechoic chamber. Alternatively, an electromagnetic wave measuring method comprising a step of transmitting and receiving a reference electromagnetic wave.