JPH06294833A - Antenna characteristics measuring apparatus - Google Patents

Abstract

PURPOSE:To provide an antenna characteristics measuring apparatus which can facilitate characteristics conducting operation (cut and try) of a reception antenna by setting measuring conditions and conformation of a measured result from a sub-measuring unit installed at a place different from a main measuring unit for automatically measuring the antenna characteristics. CONSTITUTION:A sub-measuring unit 3 is connected to a main measuring unit 2 for automatically measuring antenna characteristics through data communicating means 4. Measured conditions input from input means of the unit 3 are transmitted to the unit 2, and a measured result transmitted from the unit 2 is displayed on a display unit of the unit 3.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an apparatus for automatically measuring the frequency characteristics and directional characteristics of a receiving antenna mounted on an automobile or the like, and particularly installed at a place different from the main measuring section for automatic measurement. The present invention relates to an antenna characteristic measuring device capable of easily performing the characteristic setting work (cut and try) of a receiving antenna by enabling the measurement conditions to be set and the measurement results to be confirmed from the sub-measuring unit.

[0002]

2. Description of the Related Art FIG. 6 is a block diagram of a conventional antenna characteristic measuring apparatus. In the conventional antenna characteristic measuring device 51, the main measuring section 52 for performing automatic measurement is installed outside the anechoic chamber 8 so that the main measuring section 52 and the measurer do not affect the characteristic measurement. ing. This main measurement unit 52
Controls the frequency and level of the radio wave radiated from the transmitting antenna 5 based on the measurement conditions input from an operating unit such as a keyboard, and controls the rotation angle of the turntable 7 to form on the window glass of the automobile 9 or the like. While adjusting the direction of the received antenna 6, the signals received by the receiving antenna 6 are sequentially taken in and subjected to predetermined processing to create graphs and tables of frequency characteristics and directional characteristics, which can be displayed on a screen or displayed on a printer or the like. I am trying to get print output through.

[0003]

When adjusting the characteristics of the receiving antenna, it is necessary to perform so-called cut-and-try, in which the characteristics are repeatedly measured while changing the shape and size of the antenna. A person repeatedly travels back and forth between the receiving antenna installation location in the anechoic chamber and the main measurement unit 52 outside the anechoic chamber, for example, along the moving path W passing through the doorway 10, resulting in a time loss. . Therefore, even in the vicinity of the receiving antenna 6, the main measuring unit 52
There has been a demand for a device having a simple configuration capable of measuring the antenna characteristics with a processing procedure and a processing speed equivalent to the above.

The present invention has been made to solve such a problem, and an object thereof is to provide an antenna characteristic measuring apparatus capable of setting measurement conditions even near a receiving antenna and confirming the measurement result. Especially.

[0005]

In order to solve the above problems, an antenna characteristic measuring apparatus according to the present invention controls the frequency and level of a radio wave radiated from a transmitting antenna on the basis of an input measurement condition, and a measurement target. A main measurement unit that performs a predetermined process on a signal received by a reception antenna and outputs a characteristic measurement result of the reception antenna, and is connected to the main measurement unit via a data communication unit and input from an input unit. The sub-measuring unit is configured to transmit the measured condition to the main measuring unit and display the characteristic measurement result supplied from the main measuring unit on the display unit.

[0006]

The measuring condition input from the sub measuring unit is transmitted to the main measuring unit via the data communication means. The main measurement unit performs automatic measurement based on the measurement condition given by the sub measurement unit, and transmits the measurement result to the sub measurement unit via the data communication means. The sub measurement unit displays the transmitted measurement result on the display unit.

[0007]

Embodiments of the present invention will be described below with reference to the accompanying drawings. FIG. 1 is a block diagram of an antenna characteristic measuring device according to the present invention. This antenna characteristic measuring device 1 radiates a measurement radio wave for measurement, a main measurement unit 2, a sub measurement unit 3, a data communication unit 4 for performing data communication between the main measurement unit 2 and the sub measurement unit 3. A transmitting antenna 5, a receiving antenna 6 to be measured, and a turntable 7 for rotating the receiving antenna 6.

FIG. 1 shows a turntable 7 in an anechoic chamber 8.
It shows a case where the characteristic measurement of the receiving antenna 6 formed on the rear window glass of the vehicle 9 mounted on the vehicle is performed. The main measurement unit 2 is arranged outside the anechoic chamber 8. The sub-measuring unit 3 is arranged on the turntable 7 or in the vicinity of the receiving antenna 6 such as a rear seat of the automobile 9. The main measurement unit 2 and the sub measurement unit 3 are connected by a communication cable 4a. Reference numeral 10 is an entrance / exit for a measurer.

FIG. 2 is a block diagram of the antenna characteristic measuring apparatus. The main measurement unit 2 includes a main control unit 21 configured by a computer system, a data communication interface (I / F) unit 4b that performs data communication with the sub measurement unit 3, and
The measuring unit 22 and the like are included.

The measuring section 22 is constructed by using an impedance analyzer or the like capable of controlling operation via a measuring bus such as GP-IB. The measuring unit 22 is a main control unit 2.
A predetermined frequency signal is generated on the basis of various commands supplied from No. 1 and supplied to the transmission unit 23, and the reception unit 24
The level of the signal supplied from is measured and the measurement result is output as digital information.

The transmission signal 2a output from the transmission section 23 is sent to the transmission antenna 5 and radiated as a measurement radio wave. On the other hand, the reception signal 2b received by the reception antenna 6 is guided to the reception unit 24.

The main control unit 21 displays a menu of measurement items on the display unit 25, controls the measurement unit 23 on the basis of the measurement conditions input from the input unit 26 such as a keyboard, and if necessary. The rotation command 2c is supplied to the rotation driving unit 7a to control the rotation angle of the turntable 7 (direction of the receiving antenna 6), and the antenna characteristic is automatically measured. Then, the main control unit 21 creates a graph or table of frequency characteristics and directional characteristics based on a series of measurement data, and displays the graph or table on the display unit 25 or the printer 27.
It is configured to obtain a print output via. In addition, the measurement data may be recorded in the auxiliary storage device 28 if necessary,
It is configured so that automatic measurement and the like can be performed based on the measurement conditions read from the auxiliary storage device 28.

The main control unit 21 also checks whether or not the sub-measurement unit 3 is connected when the power is turned on or periodically, and when the sub-measurement unit 3 is connected,
The antenna characteristic is measured based on the measurement condition supplied from the sub-measurement unit 3 via the data communication unit 4, and the measurement result is transmitted to the sub-measurement unit 3, so that the sub-measurement unit 3 can also perform the measurement. Is configured as follows.

The sub-measurement unit 3 includes a sub-control unit 31, an input unit 32 such as a keyboard, a display unit 33, and a data communication interface (I / F) unit 4c. This sub measurement unit 3
Is configured using a notebook or laptop personal computer. FIG. 3 is a perspective view showing a specific example of the sub measuring unit. Then, as shown in FIG.
The data communication means 4 is constituted by the data communication interface units 4b and 4c and the communication cable 4a provided in the respective measuring units 2 and 3.

If the transmission rate of the data communication means 4 is increased so that a large amount of data can be transmitted between the main measuring section 2 and the sub measuring section 3, high frequency noise is likely to occur and the characteristic measurement of the receiving antenna 5 is adversely affected. May be caused. Therefore,
In this antenna characteristic measuring device 1, in order not to hinder the instruction transmission of the measurer and to reduce the amount of transmission data, only the data relating to the interpersonal interface relating to the designation of the measurement condition and the display of the measurement result is transmitted to the data communication means 4. It is configured to send and receive via. By reducing the amount of transmission data, GP-IB, IEEE488, IEEE422
It becomes possible to configure the data communication means by using a medium / low speed data communication method such as RS or RS-232C, which reduces the occurrence of high frequency noise and allows the data communication means 4 to operate.
Can be realized at low cost.

The interpersonal interface is composed of standard processes such as menu selection, input of measurement conditions, numerical display of measurement results, and various graph displays of measurement results, and each standard process is composed of further subdivided processes. For example, the menu processing includes processing such as an initial setting menu, a basic setting menu, an auxiliary setting menu, and a processing selection menu.

FIG. 4 is a flow chart showing an example of the data communication processing of the main measuring section. The main measurement unit 2 is the sub-measurement unit 3
Check the presence or absence of the connection with the serial poll (step S
1). When the sub measurement unit 3 is connected, a transmission request (S
RQ) Interrupt permission is issued (step S2), and the sub measurement unit 3
The operable instruction, the function number indicating the menu selection, and the information designating the menu contents are sent to the computer (step S3).

After that, the main measurement unit 2 waits for a transmission request (SRQ) interrupt from the sub measurement unit 3 (step S4), and when the transmission request (SRQ) interrupt is received, the subsequent transmission request (SRQ) interrupt is sent. After prohibiting (step S5) and confirming the transmission request (SRQ) interrupt from the sub-measuring section 3 by the serial poll (step S6), the menu number and data sent from the sub-measuring section 3 are read (step S).
7). When the process end notification is delivered from the sub measurement unit 3 (step S8), the transmission request (SRQ interrupt prohibition is released and the process proceeds to the next step.

FIG. 5 is a flow chart showing an example of the data communication process of the sub measuring unit. The flow chart of FIG.
This corresponds to the processing flow of the main measurement unit shown in FIG. The sub-measurement unit 3 side waits for data reception from the main measurement unit 2 (step S11), and when the data is received, analyzes the function number (step S12).

If the function number is menu selection, the information (data) obtained in step S11 is set as the menu content (step S13), and the menu is displayed on the display unit 33 (step S14). After this, wait for an instruction input from the measurer (step S15), and if there is an instruction input from the measurer, after transmitting a transmission request (SRQ) interrupt to the main measurement unit 2 (step S16), the above-mentioned instruction input data is sent. Is transmitted to the main measurement unit 2 (step S17), and then a process end notification is sent to the main measurement unit 2 (step S18), and this process ends.

On the other hand, if the function number is an orthogonal graph display, the information (data) obtained in step S11 is set as the graph display and related data (step S23), and the graph is displayed on the display unit 33 (step S24). . After this, a transmission request (SRQ) interrupt is transmitted to the main measurement unit 2 (step S25), then a process end notification is sent to the main measurement unit 2 (step S26), and this process ends.

If the function number is the communication of the measurement condition, the information (data) obtained in step S11 is set as the measurement condition (step S33), and the measurement condition is displayed on the display unit 33 (step S34). After that, a transmission request (SRQ) interrupt is transmitted to the main measurement unit 2 (step S35), and then a processing end notification is sent to the main measurement unit 2 (step S3).
6) and this process ends.

As described above, the interpersonal interface portion having a small amount of data is processed by the sub-measurement unit 3, and the antenna characteristic measurement operation itself is processed by the main measurement unit 2. Therefore, the sub-measurement unit 3 is connected to the receiving antenna. Even when the remote measurement is performed from the vicinity of 5, the measurement can be performed with the same measurement time and measurement accuracy as those measured by the main measurement unit 2. Moreover, the operation from the sub-measurement unit 3 and the display on the sub-measurement unit 3 are the same as the operation and the display on the main measurement unit 2. Without leaving
The situation can be grasped, and an instruction regarding antenna characteristic measurement can be given to the main measurement unit 2.

Further, the change of the processing procedure for measuring the antenna characteristics can be dealt with only by changing the processing procedure of the main measuring section 2, and the change of the processing procedure of the sub measuring section 3 side is not required. There is an advantage that maintenance and improvement of the antenna measuring device 1 are easy.

Similarly, even if the display method and the input method are slightly changed, it is possible to deal with them only by changing the processing procedure on the side of the main measuring unit 2 and not changing the processing procedure on the side of the sub-measuring unit 3.
Partial improvement is easy.

With the above configuration, when performing cut-and-try work such as setting the characteristics of the receiving antenna 5,
By placing the sub-measurement unit 3 near the receiving antenna 5 and inputting measurement conditions from the sub-measurement unit 3, the main measurement unit 2 can be remotely operated and the measurement result can be confirmed by the sub-measurement unit 3. In addition, it is possible for the measurer to move from the installation position of the sub-measurement unit 3 to the installation position of the main measurement unit 2 and continue the measurement in the middle of a series of measurements, and vice versa. You can respond flexibly.

In this embodiment, the data communication means 4 is used to transmit an electric signal. However, each data communication interface section 4b, 4c is provided with an electric-optical conversion means and an optical-electrical conversion means. With communication cable 4
By using an optical fiber cable for a, data communication can be reliably performed even in measurement in a strong electric field.
It is also possible to prevent unnecessary noise from being generated from a communication cable or the like in the measurement in a weak electric field. In addition, data may be transmitted and received using infrared rays or ultrasonic waves without using a communication cable.

Further, when the measurement of the antenna characteristics is started, a measurement start command is transmitted from the main measurement unit 2 to the sub measurement unit 3, and the sub measurement unit 3 receives the measurement start command and the sub measurement unit 3 operates, for example, an internal clock. The electromagnetic noise radiated from the sub measurement unit 3 at the time of antenna characteristic measurement may be minimized by switching to the standby mode or the like in which the measurement is stopped.

Further, although this embodiment has been described with respect to the measurement in the anechoic chamber, the antenna characteristic measuring device 1 can be applied to the measurement in the outdoors.

[0030]

As described above, in the antenna characteristic measuring apparatus according to the present invention, the main measuring unit and the sub measuring unit are connected via the data communication means, and the measuring condition can be input also from the sub measuring unit. In addition, since the measurement result of the main measurement unit is also displayed on the sub measurement unit, it is possible to measure the antenna characteristics even in the vicinity of the receiving antenna and efficiently perform the work of determining the characteristics of the receiving antenna that performs cut and try. be able to.

Further, since the sub-measurement section is configured to input the measurement conditions and display the measurement result, the sub-measurement section can be downsized and easily moved. Furthermore, since the antenna characteristics are measured in the main measurement section and the measurement results are checked in the sub measurement section, the processing speed and measurement accuracy of measurement are the same even when the measurement conditions are set from the sub measurement section. is there.

[Brief description of drawings]

FIG. 1 is a configuration diagram of an antenna characteristic measuring device according to the present invention.

FIG. 2 is a block configuration diagram of an antenna characteristic measuring device according to the present invention.

FIG. 3 is a perspective view showing a specific example of a sub measuring unit.

FIG. 4 is a flowchart showing an example of data communication processing of a main measurement unit.

FIG. 5 is a flowchart showing an example of a data communication process of a sub measurement unit.

FIG. 6 is a configuration diagram of a conventional antenna characteristic measuring device.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Antenna characteristic measuring device 2 Main measuring section 3 Sub measuring section 4 Data communication means 5 Transmitting antenna 6 Receiving antenna 32 Input section of sub measuring section 33 Display section of sub measuring section

Claims (1)

[Claims] 1. The receiving antenna, which controls the frequency and level of a radio wave radiated from a transmitting antenna based on input measurement conditions, and performs a predetermined process on a signal received by a receiving antenna to be measured. Is connected to the main measurement unit via the data communication means, transmits the measurement condition input from the input unit to the main measurement unit, and is supplied from the main measurement unit. An antenna characteristic measuring device, comprising: a sub-measurement section for displaying the characteristic measurement result on a display section.