JPH07264147A - Radio wave shield box and antenna calibration method - Google Patents

Abstract

PURPOSE:To measure the transmission reception performance accurately including an antenna characteristic of plural kinds of radio equipments whose operating frequencies differ even when the size is a size to a degree mounted on a desk top. CONSTITUTION:A radio equipment 11 having an antenna 10 is contained in a case 4 made of a metallic plate reflecting a radio wave and mounted with a test antenna 5 in the inside, and the operation of the radio equipment is tested by sending/receiving the signal with the radio equipment via the test antenna. Radio wave absorbing bodies 7, 8 are sticked to the inner side of the case in the radio wave shield box 2 and the resonance frequency fc of the test antenna 5 is set higher than the operating frequency of the radio equipment. Furthermore, the 1st radio wave absorbing body 7 absorbing a radio wave with a higher operating frequency among operating frequencies is adhered to the vicinity of the test antenna 5 in the inner face of the case and the 2nd radio wave absorbing body 8 absorbing the radio wave of the lower operating frequency among the operating frequencies is sticked to a part remote from the test antenna in the inside of the case.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a radio wave shield box for testing the operation of a radio such as a mobile phone and an antenna calibration method for calibrating a test antenna mounted in the radio wave shield box.

[0002]

2. Description of the Related Art In recent years, a mobile communication service network has been developed, and portable telephones that are installed in or carried by automobiles have become widespread even for companies and individuals.

With the spread of mobile phones, telephone companies are required to enhance after-sales service for each subscriber of the mobile phones.

Complaints brought by the subscribers of mobile phones to the service counter of the telephone company's business office can be judged to be clearly a malfunction, such as "it does not work at all," and "sometimes it may not be possible to make a call." The call is interrupted on the way. '',
There are many complaints such as "difficult to hear the other party" such as location of use, environment of use, operation error, battery consumption, etc., and it is unclear whether the cause is the actual failure or the subscriber's response.

In order to test the radio wave transmission / reception performance of a radio device that transmits and receives such radio waves, it is necessary to prevent interference radio waves from entering the antenna of the radio device under test from the outside. In particular, when the wireless device under test is a mobile phone, radio waves having a frequency in the same frequency band as the frequency used by this wireless device under test are always transmitted from a nearby base station. Cannot perform transmission / reception performance test.

[0006] Normally, such a test is carried out in a radio wave shielded test room of the radio device under test. A pseudo base station for transmitting and receiving radio waves to and from the mobile phone under test is provided in this test room.

When a dipole antenna is used as the test antenna of the pseudo base station provided in this test room, if the distance between the test antenna and the antenna of the radio device under test is extremely short, , A large mutual inductance occurs between the antennas, and the transmission / reception performance of the radio cannot be measured accurately. Therefore, it is necessary to set the distance between the antennas to a certain value or more.

Further, when the test room is narrow, each radio wave radiated from each antenna is reflected by the inner wall surface of the test room and is incident on the opponent's anthena. As a result, a direct radio wave and a reflected radio wave are directly incident on each antenna, which causes a problem such as a fading phenomenon or a pseudo increase in reception sensitivity.

[0009]

As described above, in order to measure the transmission / reception performance of the radio device to some extent accurately, a considerably large test room is required. It is practically impossible to provide such a test room, for example, in the vicinity of the service window of a telephone company office.

Therefore, in the past, when the clerk at the service window of the sales office cannot immediately identify the cause of the customer's complaint, the service of the manufacturing company provided with the test room having the above-mentioned conditions for the mobile phone is provided. I try to deliver it to the center.

Then, at this service center, a test is conducted to identify an abnormal portion, and the repaired portion is repaired. The repaired mobile phone is delivered to the original service counter and returned to the customer.

[0012] Therefore, there is a problem for the customer that he cannot judge whether the mobile phone he brought on the spot is really broken or improperly handled.

Also, at the service counter of the sales office,
Since accurate information cannot be provided to the customer immediately, service for the customer is deteriorated.

The present invention has been made in view of the above circumstances, and accurately measures the transmission / reception performance including the antenna characteristics of the radio device under test to some extent, even if the size is such that it can be installed on a desk. An object of the present invention is to provide a radio wave shielding box that can be used and a method for calibrating a test antenna mounted in the radio wave shielding box.

[0015]

SUMMARY OF THE INVENTION According to the present invention, a radio device having an antenna is housed in a case formed of a metal plate that reflects radio waves and having a test antenna mounted near one end of the inside. It is applied to a radio wave shield box for testing the operation of a wireless device by transmitting and receiving a signal to and from the wireless device via a test antenna.

In order to solve the above problems, in the present invention, a radio wave absorber is attached to the inner surface of the case, and the resonance frequency of the test antenna is set to a value higher than the frequency used by the radio device.

The invention according to claim 2 has a plurality of antennas each having an antenna in a case formed of a metal plate that reflects radio waves and having a test antenna mounted near one end of the inside, and having different operating frequencies. It is applied to a radio wave shield box for testing the operation of each radio by accommodating each type of radio individually and transmitting and receiving signals to and from each radio via a test antenna.

Further, in the present invention, the first electromagnetic wave absorber for absorbing the radio wave of the higher used frequency among the respective used frequencies is attached to the inner surface of the case in the vicinity of the test antenna, and the test antenna on the inner surface of the case is attached. A second radio wave absorber that absorbs radio waves of a low use frequency out of each use frequency is attached to a portion far from.

According to a third aspect of the present invention, in the above-mentioned second aspect of the invention, the resonance frequency of the test antenna is set to a value higher than the respective operating frequencies of the radio devices.

According to the invention of claim 4, in each of the radio wave shield boxes having the above-described structure, the radio device is supported in the case so that the antenna of the radio device housed in the case faces the test antenna. A wireless pedestal is provided.

Further, according to the invention of claim 5, a radio device having an antenna is housed in a case formed of a metal plate for reflecting radio waves, and having a test antenna mounted near one end of the inside thereof. The present invention is applied to an antenna calibration method for calibrating the gain of a test antenna in a radio wave shield box for testing the operation of a wireless device by transmitting and receiving a signal to and from the wireless device via a test antenna.

In this antenna calibration method, the calibration antenna having the known propagation coefficient is housed in the case, and the reference radio wave is output from the calibration antenna.
The test antenna receives the reference radio wave to find the propagation coefficient of the test antenna, and the gain of the test antenna is calibrated based on the found propagation coefficient.

[0023]

In the radio wave shield hox having the above-mentioned structure, the radio wave absorber is attached to the inner surface of the case formed of a metal plate that reflects radio waves. Therefore, external radio waves are prevented from entering the radio shield box. Further, a radio wave radiated from the antenna of the wireless device or a test antenna and colliding with the inner surface of the case is absorbed by the radio wave absorber and ideally hardly reflected. Therefore, in reality, even in a small case, this case can be regarded as an infinite space, and the reflected radio wave is rarely incident on the antenna on the partner side.

Further, the resonance frequency of the test antenna is set to a value higher than the frequency used by the radio device. That is,
Since the resonance frequencies of the antennas are different from each other, the test antenna is in a high-impedance state when viewed from the antenna of the radio device, and even if the distance between the antennas is set short, a large mutual inductance occurs between them. Is prevented, and the measurement accuracy of the original transmission / reception performance determination between antennas does not deteriorate.

Therefore, the radio wave shielding box as a whole can be made compact and lightweight without deteriorating the test performance.

According to the second aspect of the present invention, it is possible to test a plurality of types of radios having different frequencies used. Generally, an antenna having a high use frequency is short and an antenna having a low use frequency is long. Since the relative relationship between the test antenna and the antenna of the radio is kept constant irrespective of the used frequency, the short antenna of the radio having a high used frequency exists in the vicinity of the test antenna. Therefore, the radio waves received by the test antenna and the radio antenna propagate in a space in the immediate vicinity of the test antenna and the radio antenna. Therefore, by attaching the first radio wave absorber that absorbs the radio wave of the high use frequency to the portion on the inner surface of the case near the test antenna, the reflected wave of the radio wave of the high use frequency can be efficiently reduced.

On the other hand, a long antenna of a radio having a low operating frequency exists in a wide range from a position near the test antenna to a position relatively far from it. Therefore, by attaching the second radio wave absorber that absorbs the radio wave of the low use frequency to the far portion of the test antenna on the inner surface of the case, the reflected wave of the radio wave of the low use frequency can be efficiently reduced.

As described above, the two types of radio wave absorbers having different frequencies at which the maximum absorption efficiency is obtained are separately attached to the predetermined regions, so that one radio wave shield box can be used for a plurality of types having different use frequencies. You can test the operation of the radio.

Further, in claim 3, the resonance frequency of the test antenna is set to a value different from each used frequency. Therefore, as described above, since the frequency is different from each used frequency, it is possible to prevent the measurement accuracy of each transmission / reception performance of each radio from being deteriorated, and to set the frequency higher than each used frequency, A single test antenna can cover a wide frequency range including the above-mentioned used frequencies.

According to the fourth aspect of the invention, by mounting the pedestal of the wireless device in the case, the relative position of the antenna of the wireless device and the test antenna does not change so that each measurement between the wireless devices is performed. The error of the measured value including the deviation is suppressed.

According to the antenna calibration method of claim 5,
In order that the transmission / reception performance test result conducted using the radio wave shield box of the present invention and the transmission / reception performance test result of the radio equipment conducted in an authorized test room may coincide with each other, a plurality of radio wave shields may be provided to the same radio equipment. The gain of the test antenna is calibrated by using the calibration antenna so that the transmission / reception performance test results performed in the box match.

[0032]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described below with reference to the drawings.

FIG. 1 is an external view of a radio equipment test apparatus in which the radio wave shield box of the embodiment is incorporated.

In this radio equipment testing apparatus 1, a radio wave shield box 2 and an electronic component container 3 in which various measuring electronic components are stored are connected back to back. And
The side walls contacting each other are shared. The wireless device testing apparatus 1 of the embodiment has a height of 13 cm, a width of 32 cm, and a depth of 45 cm.
It is about the size.

In the radio wave shield box 2, a monopole type test antenna 5 is installed near one end of a case 4 formed in a box shape with a metal plate such as aluminum that reflects radio waves entering from the outside. It is fixed to the side wall on the part container 3 side.

The width of the inner surface of the case 4 including the lid 4a is slightly wider than the entire portion of the end surface 6a on the test antenna 5 side, the bottom surface 6b, both side surfaces 6c, and the inner surface 6d of the lid 4a facing the test antenna 5. The first electromagnetic wave absorber 7 is attached to L ₁ .

Further, the bottom surface 6b, both side surfaces 6c, and the lid 4a.
A second electromagnetic wave absorber 8 having a predetermined width L ₂ is attached to a position adjacent to the first electromagnetic wave absorber 7 on the inner surface 6d.

In the radio wave shield box 2 of the embodiment shown in FIG. 1, the second radio wave is applied to the inner surface of the case 2 where the first and second radio wave absorbers 7 and 8 are not attached. The absorber 8 is attached.

The first electromagnetic wave absorber 7 is made of, for example, a rubber ferrite material, and the thickness d ₁ thereof is set to 6,3 mm. The absorption characteristic of the first electromagnetic wave absorber 7 having this thickness d ₁ (= 6.3 mm) shows a maximum value at 1.5 GHz. That is, it most efficiently absorbs radio waves having a frequency of 1.5 GHz.

The second electromagnetic wave absorber 8 is the first electromagnetic wave absorber 7.
And the thickness d ₂ is set to 6, 7 mm. The absorption characteristic of the second electromagnetic wave absorber 8 having this thickness d ₁ (= 6.7 mm) shows a maximum value at 800 MHz. That is, it absorbs a radio wave having a frequency of 800 MHz most efficiently.

A radio receiver 9 is mounted on the bottom surface 6b of the radio wave shield box 2 at a predetermined position. Then, the mobile phone 11 as a wireless device with the antenna 10 extended is placed on the wireless device support 9. The radio receiver 9 has a function of always keeping the position of the mobile phone 11 in the radio wave shield box 2 constant so that the antenna 10 accurately faces the test antenna 5.

As shown in FIG. 2, on the front surface of the mobile phone 11, there is provided an operation panel 13 having a display 12 and a large number of operation buttons including dial buttons. Further, an external interface terminal 14 is provided on the lower surface. When carrying out an operation test on the mobile phone 10, the connection cable 15 is connected to the external interface terminal 14.

On the upper surface of the electronic component container 3, there is provided a paper discharge port 16 for discharging the paper on which the test results are printed.
Further, on the front surface of the electronic component container 3, a display lamp 17a. 17b. 17c, a plurality of selection keys 19 for inputting the type of the mobile phone 11 to be tested, a model display 19a, a test start key 20a, and a test stop key 2
0b, a print key 21 for instructing print output of test results, and a power switch 22 are provided.

There are two types of frequencies used by the portable telephone 11 which can be tested by the radio equipment testing device 1, 800 MHz and 1.5 GHz. 1.5G shown in FIG.
Antenna 10 of mobile phone 11a using a frequency of Hz
a is about half the length of the antenna 10b of the mobile phone 11b using the frequency of 800 MHz shown in FIG.

Here, in order to measure the transmission and reception performances of the mobile phones 11a and 11b under the same conditions, the relative positions of the antennas 10a and 10b and the measurement antenna 5 are shown in FIGS. ), They must match. Therefore, dedicated radio receivers 9a and 9 are provided.
Mobile phone 11 to be tested with b prepared
The radio receiver pedestals 9a and 9b corresponding to the types of a and 11b are fixed to the locking portions projecting on the bottom surface 6b in the radio wave shield box 2. Then, the corresponding mobile phone 11
The a and 11b are placed on the radio pedestals 9a and 9b. Therefore, even if the model of the mobile phone 11 is changed, each antenna 10 of the mobile phones 11a and 11b is changed.
The relative position between a and 10b and the test antenna 5 does not change.

Therefore, the radio waves transmitted and received between the antenna 10a of the mobile phone 11a and the test antenna 5 using the frequency of 1.5 GHz are 1. It propagates in the space where the first electromagnetic wave absorber 7 having the maximum absorption characteristic at 5 GHz is attached. Therefore, the radio wave reflected on the inner surface of the case 4 is transmitted to each antenna 10
There is almost no incidence on a and 5.

Further, the antenna 10b and the test antenna 5 of the mobile phone 11b using the frequency of 800 MHz.
As shown in FIG. 3 (b), the radio waves transmitted and received between the first radio wave absorber 7 having the maximum absorption characteristic at 1.5 GHz and the second radio wave absorber having the maximum absorption characteristic at 800 MHz are shown in FIG.
Propagates through the space where the radio wave absorber 8 is attached. However, since radio waves are transmitted and received by the entire antenna 10b,
Most of the 800 MHz radio wave that collides with the inner surface of the case 4 is absorbed by the second radio wave absorber 8. Therefore, the radio wave reflected on the inner surface of the case 4 hardly enters the antennas 10b and 5 respectively.

Further, the resonance frequency f _C of the test antenna 5
Is the operating frequency of each mobile phone 11a, 11b 1.5G
It is set to a value slightly higher than Hz and 800 MHz.

As shown in the antenna gain characteristics A and B of FIG. 4, the antennas 10a.
In 10b, each resonance frequency is set so that the maximum gain can be obtained at each use frequency of 1.5 GHz and 800 MHz. Therefore, the resonance frequency f _C is 1.5 GHz, 8
The antenna gain characteristic C of the test antenna 5 higher than 00 MHz is 1.5 G lower than the resonance frequency f _C as shown in the figure.
It covers a wide frequency range including Hz and 800 MHz.

In this way, the resonance frequency f _C of the test antenna 5 is set to a value higher than the operating frequencies of 1.5 GHz and 800 MHz of the mobile phones 11a and 11b. As a result, the test antenna 5 and each antenna 10a. 10b
Since the resonance frequencies are different from each other, the test antenna 5 is the antenna 10 of each of the mobile phones 11a and 11b.
a. The high impedance state is seen from 10b, and even if the distance between the antennas is set short, a large mutual inductance is prevented from occurring between them.

As a result, each antenna 5, 10a, 10b
Since the apparent reception gain does not change, the measurement accuracy of the transmission / reception performance in each of the mobile phones 11a and 11b under test does not decrease.

Next, in this way, the operating frequencies of the mobile phones 11a and 11b to be tested are intentionally set to 1.5 GHz and 80 GHz, respectively.
A method of correcting the reception level and the transmission level in the case of receiving and transmitting a radio wave with each of the mobile phones 11a and 11b by the test antenna 5 having a resonance frequency f _C slightly higher than 0 MHz will be described.

The gains of 1.5 GHz and 800 MHz on the antenna gain characteristic C of the test antenna 5 in FIG. 4 are Ga and Gb. Each mobile phone 11a, the antenna 10a of 11b, when the maximum gain (gain) G _M of 10b and the test antenna 5 Assuming equal, 1.5 GHz between the cellular telephone 11a and the test antenna 5 The gain G obtained by the test antenna 5 when transmitting and receiving a radio wave of a frequency is compared with the gain of a regular base station antenna in which the test antenna 5 has a resonance frequency of 1.5 GHz, the Ga / G _M) multiplied by value. Accordingly, the received level of the received radio wave obtained by the test antenna 5 (G _M / Ga) multiplied by if correct reception level is obtained.

From the test antenna 5 to the mobile phone 1
When transmitting a 1.5 GHz radio wave to 1a, the output of the transmission signal applied to the test antenna 5 is (G _M / G
a) If the cell phone 11a is raised twice,
It is possible to recognize and receive a radio wave transmitted from an antenna of a regular base station having a resonance frequency of GHz.

That is, the signal level transmitted and received by the test antenna 5 to the mobile phone 11a is (G _M
/ Ga).

Similarly, the test antenna 5 and the mobile phone 1
The gain G obtained by the test antenna 5 when transmitting and receiving a radio wave of a frequency of 800 MHz to and from 1b is
This test antenna 5 has a gain of (Gb /
G _M ) times the value. Accordingly, the received level of the received radio wave obtained by the test antenna 5 (G _M / Gb)
The correct reception level can be obtained by multiplying. Also, 800M
Even when transmitting the radio wave of Hz to the mobile phone 11b,
It suffices to multiply the transmission output (G _M / Gb).

The absolute value of the antenna gain of the test antenna 5 is calibrated in advance in order to quantitatively measure the transmission / reception performance of each of the mobile phones 11a and 11b to be tested and to judge the quality. There is a need. A procedure for calibrating the test antenna 5 will be described.

First, the radio wave shield box 2 shown in FIG.
In each of the mobile phones 11a. Instead of 11b, the calibration antenna is stored at a predetermined position. In order to always control the storage position of this calibration antenna to a fixed position, the pedestal dedicated to the calibration antenna is used as the above-mentioned wireless device cradle 9
The same method is used to mount and fix it on the bottom surface 6b of the radio wave shield box 2.

The calibration antenna is prepared for each frequency. Each calibration antenna is, for example, a dipole antenna that resonates at each frequency. Then, a reference signal is applied to this calibration antenna from a separately prepared reference signal generator, and a reference radio wave is output from the calibration antenna.

The reference antenna is received by the test antenna 5. The propagation coefficient of the test antenna 5 is obtained. Then, based on this propagation coefficient, the antenna gain (gain) indicated by a relative value with respect to the calibration antenna at each frequency f of the test antenna 5 is obtained.

Regarding the frequency characteristics, the mutual relationship of the frequency characteristics of the antenna coefficient of the standard antenna such as a separately calibrated dipole antenna and the calibration antenna is obtained in advance by the replacement method. Then, the frequency characteristic of the calibration antenna is corrected to the antenna gain of the test antenna 5.

In this way, each operating frequency is 1.5 GHz, 8
Using one type of test antenna 5 that requires a resonance frequency f _C higher than 00 MHz, a plurality of types of mobile phones 11a. It is possible to normally transmit and receive signals by radio waves to and from 11b. Furthermore, it is possible to quantitatively test the transmission performance and the reception performance of the mobile phones 11a and 11b to be tested.

Further, since the gain of the test antenna 5 is calibrated with the standard antenna as a reference, each of the mobile phones 11a and 11 which is performed by using the radio wave shield box 2 is calibrated.
b transmission / reception performance test results and each mobile phone 1 that was tested in an authorized test room at a service center of a manufacturing plant, for example.
Correlation can be obtained with the transmission / reception performance test results of 1a and 11b. Further, the transmission / reception performance test results of the plurality of radio wave shield boxes 2 for the same mobile phone do not become inconsistent. Therefore, the reliability of the test result at the service window can be significantly improved.

In the radio equipment test apparatus 1 in which the radio wave shield box 2 constructed as described above is incorporated, the operator mounts the radio equipment cradle 9 corresponding to the model of the mobile phone 11 to be tested on the bottom surface 6b. The mobile phone 11 with the antenna 10 extended and the radio wave shield box 2
Place it on the radio receiver 9 inside, close the lid 4a, specify the model of the relevant mobile phone 11 with the model selection key 19,
Press the test start key 20a. Then, a signal is automatically transmitted / received between the test device side and the mobile phone 11 with a radio wave of a frequency of 800 MHz or 1.5 GHz corresponding to the relevant model, and a test result including a transmission / reception level judgment is displayed by a display lamp. 17a to 17c.

Therefore, even if the radio wave shield box 2 has a small volume so that it can be easily installed at the service counter of the telephone company's business office, the operation of a plurality of types of mobile phones 11 having different frequencies can be performed easily and accurately. Can test.

The present invention is not limited to the above embodiment. In the apparatus of the embodiment, the mobile phone 1
Although 1 is the wireless device to be tested, any wireless device having a function of converting information transmitted and received by radio waves into digital information and processing it may be used. The frequency used is 800 MHz and 1.
It is not limited to 5 GHz.

[0067]

As described above, according to the radio wave shield box of the present invention, the radio wave absorber is attached to the inner surface of the case, and the resonance frequency of the test antenna is set to a value higher than the frequency used by the radio device. There is. Therefore, it is possible to measure the transmission / reception performance including the antenna characteristic of the wireless device under test to some extent accurately, even if it is large enough to be installed on the desk.

Further, a first electromagnetic wave absorber that absorbs a radio wave having a high frequency among the frequencies used is attached to a portion of the inner surface of the case near the test antenna, and a first electromagnetic wave absorber for absorbing a radio wave of a high frequency of each frequency is attached to a portion far from the test antenna on the inner surface of the case. A second radio wave absorber that absorbs radio waves of low frequencies among the frequencies used is attached. Therefore, with one radio wave shield box, it is possible to accurately carry out an operation test of a plurality of types of wireless devices having different operating frequencies.

Further, a calibration antenna having a known propagation coefficient is housed in the case, a reference radio wave is output from the calibration antenna, and the reference antenna is received by the test antenna to calibrate the gain of the test antenna. is doing. Therefore, the compatibility of the test performed in the regular radio wave shield test room and the test result performed using another radio wave shield box can be ensured, and the reliability of the test can be improved.

[Brief description of drawings]

FIG. 1 is an external view of a radio device testing apparatus incorporating a radio wave shield box according to an embodiment of the present invention.

FIG. 2 is an external view showing a wireless receiver and a mobile phone to be tested, which are housed in a radio wave shield box of the embodiment.

FIG. 3 is a diagram for explaining the operation of the radio wave shield box of the embodiment.

FIG. 4 is a diagram showing antenna gain characteristics of each antenna.

[Explanation of symbols]

1 ... Radio equipment testing device, 2 ... Radio wave shield box, 3 ...
Electronic component container, 4 ... Case, 5 ... Test antenna, 7 ...
1st electromagnetic wave absorber, 8 ... 2nd electromagnetic wave absorber, 9 ... Radio | wireless machine pedestal 10,10a, 10b ... Antenna, 11,1
a, 11b ... mobile phone, 12 ... indicator, 13 ... operation panel

─────────────────────────────────────────────────── ─── Continuation of the front page (51) Int.Cl. ⁶ Identification code Internal reference number FI Technical indication H05K 9/00 M

Claims (5)

[Claims] 1. A radio (11) having an antenna (10) in a case (4) formed of a metal plate that reflects radio waves, and having a test antenna (5) mounted near one end of the inside. ) Is stored in the radio shield box (2) for testing the operation of the radio by transmitting and receiving signals to and from the radio via the test antenna. A radio wave shield box, characterized in that a radio wave absorber (7, 8) is attached to and a resonance frequency of the test antenna is set to a value higher than a frequency used by the radio device. 2. A case (4) formed of a metal plate that reflects radio waves, and having a test antenna (5) mounted near one end of the inside, has an antenna (10) and uses frequencies different from each other. A plurality of different types of radios (11a, 11b) are individually housed, and signals are transmitted to and received from the radios via the test antenna.
1a, 11b) radio wave shield box for testing operation
In (2), a first radio wave absorber (7) that absorbs radio waves of a high frequency among the frequencies used is attached to a portion of the inner surface of the case near the test antenna, and the first electromagnetic wave absorber (7) is attached to the inner surface of the case. A radio wave shield box, characterized in that a second radio wave absorber (8) that absorbs radio waves of a lower use frequency among the above use frequencies is attached to a portion far from the test antenna. 3. The radio wave shield box according to claim 2, wherein the resonance frequency of the test antenna is set to a value higher than the respective operating frequencies of the radio devices. 4. A radio receiver base (9) for supporting the radio is provided in the case so that the antenna of the radio housed in the case faces the test antenna. The radio wave shield box according to claim 2 or 3, characterized in that. 5. A radio device having an antenna is housed in a case formed of a metal plate that reflects radio waves, and a test antenna is attached near one end of the inside of the case. In the antenna calibration method for calibrating the gain of the test antenna in the radio wave shield box for testing the operation of the radio by transmitting and receiving a signal to and from the radio, a known propagation coefficient in the case The calibration antenna having is stored and the reference radio wave is output from this calibration antenna,
An antenna calibration method for receiving the reference radio wave with the test antenna, obtaining a propagation coefficient of the test antenna, and calibrating the gain of the test antenna based on the obtained propagation coefficient.