JP2007132718A - Obstruction exclusion capability testing device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To use a low cost and low output power amplifier. <P>SOLUTION: An obstruction exclusion capability testing device for testing the obstruction exclusion capability of under testing equipment by radiating radio wave to the under testing equipment placed at the receiving point from the radiation antenna. On the behind of the under testing equipment, reflection plates for reflecting the radio wave radiated from the radiation antenna are constituted so as to reflect the radio wave to the receiving point in such a manner that at the receiving point the resultant electric power of the reflected radio wave reflected by the reflectors and the radio wave radiated from the antenna becomes maximum. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

The present invention relates to a disturbance rejection capability test apparatus for testing a disturbance rejection capability (also referred to as immunity) of an electronic device.

Conventionally, in an immunity test apparatus, the EUT is placed on a turntable that stands on one end of an anechoic chamber, and an antenna is provided on an antenna support column that stands on the other end. And it is comprised so that the electromagnetic waves radiated | emitted from the antenna may be poured on the test plane in which the test equipment is set | placed (for example, refer patent document 1).
In addition, as a test method, a specimen is placed in an anechoic chamber, and a radiated electromagnetic field in which horizontal or vertically polarized electromagnetic waves are applied to the specimen from a biconical antenna or a log periodic antenna fixed in the same anechoic chamber. A test method, a TEM waveguide method using a TEM cell, a GTEM cell, and the like are known, and there is also a method of applying a rotating electromagnetic field to the specimen (for example, see Patent Document 2).

JP-A-7-55863 JP 2003-98211 A

By the way, in the immunity test, if the electric field strength of the test radio wave radiated from the antenna is not increased and evaluated, sufficient immunity test may not be performed depending on the usage condition of the product under test (test equipment). there were.

In other words, for example, when the product is mounted on a moving body such as an automobile, and the moving body travels near a guidance radar device used for taking off and landing of an aircraft, the electric field strength of 200 V / m. If an immunity test is performed using test radio waves, even if the immunity test is passed, there may be a problem that an electronic device malfunctions and does not function correctly, or in some cases a fatal failure may occur. It was.

Therefore, in recent years, in the immunity test, the electric field strength of the test radio wave is changed to 600 V / m as a test condition.
However, when realizing this field strength of 600V / m with a single amplifier / antenna as in the above proposed technique, not only a high withstand voltage antenna is required but also a high output power. There is a problem that a power amplifying device is necessary, and the interference exclusion capability testing device is physically increased in size and cost is increased.

The present invention has been made in view of these problems, and an object of the present invention is to provide an interference rejection capability test apparatus that can use a low-cost low-output power amplifier.

  In order to solve the above-mentioned problem, the invention of claim 1 is used to test the ability of the EUT to eliminate interference by radiating electromagnetic waves from the radiating antenna toward the EUT placed at the receiving point. In the interference exclusion capability test apparatus, a reflection plate for reflecting the electromagnetic wave radiated from the radiation antenna is provided behind the reception point, and the reflection plate transmits the electromagnetic wave radiated from the radiation antenna. The antenna is configured to reflect toward the reception point, and at the reception point, the combined power of the electromagnetic wave reflected by the reflector and the electromagnetic wave radiated from the radiation antenna is maximized.

According to a second aspect of the present invention, in the interference rejection capability testing apparatus according to the first aspect, the reflecting plate is constituted by at least two reflecting plates.

According to a third aspect of the present invention, there is provided the interference rejection capability testing apparatus according to the second aspect, wherein the reflecting plate has a perpendicular line passing through a center point of the reflecting plate, and the receiving antenna and the receiving device viewed from the center point of the reflecting plate. The angle formed by the point is divided in two, and the distance from the radiation antenna to the center point of the reflector and the center point of the reflector to the reception point, and the distance between the radiation antenna and the reception point, Are arranged so as to be an integral multiple of half the wavelength of the electromagnetic wave radiated from the radiation antenna.

According to a fourth aspect of the present invention, in the interference rejection capability testing apparatus according to any one of the first to third aspects, the radiation antenna includes an electromagnetic horn and a central axis that is the same axis as the radial axis of the electromagnetic horn. And a waveguide arranged between the electromagnetic horn and the EUT so as to be on a line.

According to a fifth aspect of the present invention, in the interference rejection capability testing device according to any one of the first to fourth aspects, the radiating antenna is configured to radiate linearly polarized electromagnetic waves.

According to the invention of claim 1, the interference exclusion capability test used to test the interference rejection capability of the EUT by radiating electromagnetic waves from the radiating antenna toward the EUT placed at the receiving point. In the apparatus, a reflection plate for reflecting the electromagnetic wave radiated from the radiation antenna is provided behind the reception point, and the reflection plate reflects the electromagnetic wave radiated from the radiation antenna toward the reception point. And arranged so that the combined power of the electromagnetic wave reflected by the reflecting plate and the electromagnetic wave radiated from the radiation antenna is maximized at the reception point.
The radio waves radiated from the radiating antenna can be efficiently collected at the receiving point, and the test radio waves with strong electric field strength can be applied by the equipment under test.
In addition, since the receiving field strength can be increased by providing a reflector, the output of the transmission amplifier connected to the radiation antenna can be suppressed, and the design of the transmission amplifier (high output, heat dissipation structure) is easy. As a result, product costs can be reduced.

According to the invention of claim 2, in the interference exclusion capability test apparatus according to claim 1, since the reflector is constituted by at least two reflectors,
For example, the packing state at the time of shipment can be reduced and the transportation cost can be reduced. In addition, since the reflectors are formed in a size that can be easily handled, handling during installation is simplified.

According to a third aspect of the present invention, in the interference rejection capability testing device according to the second aspect, the reflector has a perpendicular line passing through the center point of the reflector plate and the radiation antenna viewed from the center point of the reflector plate. The receiving point is arranged in a direction that bisects the angle formed by the receiving point, and the distance between the center point of the reflecting plate from the radiating antenna and the receiving point from the center point of the reflecting plate, and the radiating antenna and the receiving point Since the difference from the distance is an integer multiple of half the wavelength of the electromagnetic wave radiated from the radiation antenna,
It is possible to simplify the installation of the radiation antenna and the reflector so that the combined power at the reception point is maximized.

According to a fourth aspect of the present invention, in the interference rejection capability testing apparatus according to any one of the first to third aspects, the radiation antenna includes an electromagnetic horn and a central axis that is the same axis as the radial axis of the electromagnetic horn. Since it is configured to comprise a waveguide disposed between the electromagnetic horn and the EUT so as to be on a line,
The electromagnetic horn from the electromagnetic horn can be radiated efficiently to the EUT, and the radiation path from the electromagnetic horn to the EUT is compared with the case where the electromagnetic horn is simply radiated. It is possible to reduce the loss of electromagnetic waves generated, and to apply test electric waves with stronger electric field strength to the EUT.

According to a fifth aspect of the present invention, in the interference rejection capability testing device according to any one of the first to fourth aspects, the radiation antenna is configured to radiate linearly polarized electromagnetic waves.
It is possible to easily synthesize radio waves at the reception point using the reflector.

Embodiments of the present invention will be described below with reference to the drawings.
First, FIG. 1 is a configuration diagram showing the overall configuration of an interference rejection capability test apparatus (hereinafter referred to as an EMC test apparatus) of this embodiment.

As shown in FIG. 1, the EMC test apparatus according to the present embodiment is used for testing toward the test object 2 placed at the reception point in order to perform an immunity test for measuring the resistance of the test object 2 due to an interference wave. An oscillator 12 for generating a high-frequency signal to be a test radio wave, an amplifier 14 for amplifying the high-frequency signal output from the oscillator 12 to a predetermined level, and the amplifier 14 receives the high frequency signal amplified at 14 and radiates the test radio wave toward the test object 2 and reflects the test radio wave radiated from the radiation antenna 10 toward the test object 2. And a reflector 20 for the purpose.

The radiating antenna 10 includes a rectangular electromagnetic horn 16 that is open on one side, and a rectangular waveguide 18 having an opening formed so as to have the same shape as the opening surface of the electromagnetic horn 16.
The electromagnetic horn 16 is installed at a predetermined height position in the electromagnetic wave anechoic chamber 4 for EMC testing via a support 6a, and the waveguide 18 is connected to the radiation axis of the test radio wave radiated from the electromagnetic horn 16. The wave tube 18 is installed in the anechoic chamber 4 via the support 6b so that the central axes thereof coincide with each other.
The waveguide 18 is for efficiently radiating the electromagnetic wave from the electromagnetic horn 16 to the EUT. The waveguide 18 and the electromagnetic horn 16 are in a state in which both end faces thereof are in close contact with each other. is set up. That is, by providing this waveguide 16, it is possible to reduce the loss of electromagnetic waves generated in the radiation path from the electromagnetic horn to the EUT, compared to the case where electromagnetic waves are simply emitted from the electromagnetic horn. This is intended to enable a test radio wave having a strong electric field strength to be applied to the EUT.
The waveguide 18 is formed of a conductive material. However, the waveguide 18 may be formed of a fiber woven with a conductive material, and may have a gap shorter than a quarter of the wavelength at the frequency used. For example, it may be formed in a mesh shape. Thus, if it forms in fiber or mesh shape, the weight reduction of a waveguide will be attained. In this embodiment, a rectangular electromagnetic horn and a rectangular waveguide are used, but a circular electromagnetic horn and a circular waveguide may be used.
The test object 2 is placed on a table 8 placed at a predetermined distance from the radiation antenna 10 in the anechoic chamber 4.
The reflection plate 20 is formed in a metal plate shape such as iron or aluminum.
Two reflectors 20 are arranged on the table 8 on the side opposite to the radiation antenna 10 side of the test object 2, and the test radio wave radiated from the radiation antenna 10 is directed toward the test object 2. It is installed at a position where it can be reflected.

As described above, in the EMC test apparatus of the present embodiment, when a high-frequency signal from the oscillator 12 is input to the radiation antenna 10 via the amplifier 14, the test radio wave is directed from the radiation antenna 10 toward the test object 2. Radiate. Then, the test radio wave radiated from the radiation antenna 10 is applied to the test object 2 and reflected by the reflecting plate 20, and the test radio wave reflected by the reflecting plate 20 is also applied to the test object 2. .
That is, in the EMC test apparatus of this embodiment, the test radio wave radiated from the radiation antenna 10 and the test radio wave reflected by the reflector 20 are radiated to the test object 2.
For this reason, according to the EMC test apparatus of the present embodiment, the test object 2 radiated from the radiation antenna 10 can be efficiently irradiated to the test object 2 as compared with the conventional EMC test apparatus that does not use the reflector 20. Therefore, the electric field strength of the test radio wave at the installation point of the test object 2 can be increased.
Therefore, when the electric field strength of the test radio wave irradiated on the test object 2 is determined, the output of the amplifier 14 can be reduced as compared with the conventional EMC test apparatus. Test equipment can be realized at low cost.

Next, an experiment conducted for verifying the above effect will be described with reference to FIG.
First, in this experiment, as shown in FIG. 2 (a), 1 m (from the opening end face of the waveguide 18 on the table 8 side) of the opening end face of the radiating antenna 10 on the radiating axis of the radiating antenna 10 An electric field probe for measuring the received electric field strength is disposed at a position (reception point) separated by 100 cm) or 1.1 m (110 cm), and two reflectors 20 are placed from the radiation antenna 10 behind the electric field probe. The test radio wave was placed at a position where it could be reflected toward the electric field probe.
The area of the reflecting plate 20 (specifically, the area of the reflecting surface of the reflecting plate 20) is 200 cm 2 (vertical × horizontal: 10 cm × 20 cm), 600 cm 2 (vertical × horizontal: 20 cm × 30 cm), 1200 cm 2 (vertical × The width of the received electric field probe was used to measure the received electric field strength. Further, as a comparative example, the same measurement was performed for a case where the reflector 20 was not disposed.
Next, the measurement results are shown in FIGS. This measurement result is a measurement result when the frequency f of the electromagnetic wave radiated from the radiation antenna 10 is set to 2.9 GHz.
As is clear from FIGS. 2B and 2C, it was found that the received signal intensity at the electric field probe is greater when the reflector 20 is disposed than when the reflector 20 is not disposed. . Further, it was found that when the reflecting plate 20 is disposed, the received signal intensity at the electric field probe increases as the reflecting surface having a larger area is used.
Therefore, based on the measurement results described above, the EMC test apparatus of the present embodiment can increase the received electric field strength of the test object 2 as compared with the conventional EMC test apparatus that does not use the reflector 20.

In addition, although the electromagnetic wave f in embodiment of this application showed the example which uses a 2.9 GHz band, for example, f = 1.3 GHz band may be sufficient, for example, it is not limited to this Example. In this embodiment, the distance between the opening end face of the radiating antenna 10 and the electric field probe for measuring the received electric field strength is set to 1 to 1.1 m, but it is optimally appropriate depending on the frequency of the electromagnetic wave radiated from the radiating antenna. It may be adjusted so as to be in a proper position.
Next, the basic concept for determining the arrangement position of the reflector will be described. That is, a perpendicular line passing through the center point of the reflector is arranged in a direction that bisects the angle formed by the radiation antenna 10 and the reception point viewed from the center point of the reflector, and from the radiation antenna 10 to the reflector. And the distance between the center point of the reflector and the reception point from the center point of the reflector, and the distance between the radiation antenna 10 and the reception point (that is, the distance between the opening end face of the radiation antenna 10 and the field probe for measuring the reception field strength). ) Is reflected toward the reception point by the direct wave from the radiation antenna 10 and the reflection plate 20 if it is arranged so as to be an integral multiple of half the wavelength of the electromagnetic wave radiated from the radiation antenna 10. The reflected waves are combined with each other without canceling each other, so that the EUT can be efficiently irradiated with electromagnetic waves.

As mentioned above, although one Embodiment of this invention was described, it cannot be overemphasized that this invention can take a various form.
In the present embodiment, two reflecting plates 20 are used. However, the present invention is not limited to this, and the reflecting plate 20 performs a test so as to reflect the test radio wave emitted from the radiation antenna 10 toward the test object 2. Any number of sheets may be used as long as they are arranged behind the object 2.
By the way, when the test radio wave reflected by the reflecting plate 20 is received by the radiation antenna 10, the received signal enters the amplifier 14 and the amplifier 14 breaks down.
For this reason, it is desirable that the reflecting plate 20 is disposed at a position where the test radio wave is reflected toward the test object 2 and at a position where the reflected test radio wave is not received by the radiation antenna 10. The shape of the reflecting surface of the reflecting plate 20 should be concave.
Further, the radiating antenna may be constituted only by the electromagnetic horn 16 without the waveguide 18.

Note that the present invention is not limited to the above-described embodiment, and the configuration of each part can be appropriately changed and implemented without departing from the spirit of the present invention.

It is a block diagram showing the structure of the whole EMC testing apparatus of this embodiment. It is explanatory drawing explaining the experiment conducted in order to prove the effect of this embodiment.

Explanation of symbols

2 ... test object, 4 ... anechoic chamber, 8 ... table, 10 ... radiating antenna, 12 ... oscillator, 14 ... amplifier, 16 ... electromagnetic horn, 18 ... waveguide, 20 ... reflector.

Claims (5)

In a disturbance immunity testing device used to test the disturbance immunity of a EUT by radiating electromagnetic waves from the radiating antenna toward the EUT placed at the receiving point.
A reflection plate for reflecting the electromagnetic wave radiated from the radiation antenna is provided behind the reception point, and the reflection plate is configured to reflect the electromagnetic wave radiated from the radiation antenna toward the reception point. In addition, the interference rejection capability testing apparatus is arranged so that the combined power of the electromagnetic wave reflected by the reflector and the electromagnetic wave radiated from the radiation antenna is maximized at the reception point.
2. The interference rejection capability testing apparatus according to claim 1, wherein the reflection plate comprises one or more reflection plates.
The reflecting plate is arranged in a direction in which a perpendicular passing through the center point of the reflecting plate divides the angle formed by the radiating antenna and the receiving point viewed from the center point of the reflecting plate, and is reflected from the radiating antenna. The difference between the distance between the center point of the plate and the center point of the reflector and the reception point and the distance between the radiation antenna and the reception point is an integer of a half wavelength of the electromagnetic wave radiated from the radiation antenna. The interference wave capability testing apparatus according to claim 2, wherein the apparatus is arranged so as to be doubled.
The radiation antenna comprises an electromagnetic horn and a waveguide disposed between the electromagnetic horn and the EUT so that the central axis is on the same axis as the radiation axis of the electromagnetic horn. The interference exclusion capability test apparatus according to any one of claims 1 to 3.
5. The interference rejection capability testing apparatus according to claim 1, wherein the radiation antenna is configured to radiate linearly polarized electromagnetic waves. 6.

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