JPH0515104Y2 - - Google Patents

Description

[Detailed Description of the Invention] (Industrial Application Field) The present invention relates to an improvement in a field strength measuring device used for measuring interference waves, urban noise, and radio waves generated from digital electronic devices and automobiles.

(Prior Art) As the number of electronic devices and automobiles increases, interference waves are emitted from their digital circuits, ignitions, etc., and the electromagnetic environment tends to deteriorate year by year. In particular, advances in LSI manufacturing technology have led to the remarkable spread of digitized electronic equipment, and it has become easier to incorporate faster elements and microprocessors into electronic equipment.
It continues to increase both in quantity and frequency.
On the other hand, in order to protect the electromagnetic environment, each country establishes in advance the permissible limits of interference waves based on objects subject to regulation, such as electronic equipment and automobiles, and monitors whether or not the interference waves from such objects are within the permissible limits. is strengthening.

Therefore, due to the above requirements, it is very important to measure the electric field strength in the air, and various electric field strength measuring devices have been developed from this point of view.

By the way, the electric field strength E (dBμv/m) is generally expressed by the following formula.

E=V(dBμv)+K(dB) However, V is the measured value measured using the antenna,
K is an antenna coefficient, which is a known value that varies depending on the type of antenna, such as a dipole antenna, a loop antenna, etc., and the reception frequency of the antenna. Therefore, in this type of measuring device, after measuring the measured value V, the antenna coefficient K is appropriately calculated to obtain the electric field strength E.

By the way, this type of field strength measuring device can be used not only for antennas and high frequency attenuators, but also for mixers,
It is composed of a local oscillator, an intermediate frequency attenuator, an amplifier, a receiver such as a detector, an indicator, etc., and the measured value V is a combination of the attenuation of the high frequency attenuator, the attenuation of the intermediate frequency attenuator, and the indicator. The electric field strength E is calculated by adding an antenna coefficient K depending on the receiving frequency of the antenna to the measured value V.

Conventionally, when measuring the electric field strength E using the above-mentioned apparatus, there are two methods: one is to measure the electric field strength by digitally adding antenna coefficients, and the other is to measure the electric field strength by using an antenna coefficient table. The former measurement method involves converting both the attenuation of the high-frequency attenuator and the intermediate frequency attenuator and the indicated value of the indicator into digital data, and then digitally processing this digital data and the predetermined antenna coefficient. For example, the electric field strength can be easily determined and the electric field strength can be displayed digitally. On the other hand, the latter measurement method involves preparing in advance an antenna coefficient table that associates each frequency (MHz) with an antenna coefficient (dB), finding the antenna coefficient from the coefficient table according to the reception frequency, and then The electric field strength E is measured from the coefficient and the measured value.

(Problem that the invention attempts to solve) However, in the former measurement method, in practice,
It is necessary to know what the actual measurement value V including the attenuation amount of the attenuator is, and for this purpose, the received output is displayed digitally. However, in many cases where the received output is displayed digitally, discontinuous waves are measured which change very drastically due to the nature of the measurement target itself, and therefore the digitally displayed indicated value changes drastically and cannot be seen by human vision. It is difficult to read directly, and even if you can read the indicated value, it lacks accuracy.

Next, the latter method using the antenna coefficient table is as follows:
Usually, the antenna coefficient table is placed in a card case and installed in an appropriate location, or the antenna coefficient table is printed in the instruction manual in advance, but these are complicated to store and have problems such as loss. In addition, if a large number of frequencies are listed in detail in order to improve the accuracy of frequency reading, the content of the search becomes enormous, and there are problems in that it takes a long time to find a specific frequency and that reading errors are likely to occur.

The present invention was developed in view of the above-mentioned circumstances, and uses a simple circuit configuration to display the receiver output in an analog manner and digitally display the antenna coefficient, thereby easily and accurately measuring the electric field strength. The purpose of the present invention is to provide an electric field strength measuring device that can be used to measure electric field strength.

(Means for Solving the Problems) The field strength measuring device according to the present invention has a memory that stores coefficient values of a plurality of antennas, each of which is determined in advance according to the type of antenna and the frequency characteristics of the antenna. a receiving section that receives a signal extracted through one antenna in a certain frequency band; an indicator that displays the reception output of this receiving section in analog form; the type of the antenna and the receiving frequency sent from the receiving section; an arithmetic processing unit that reads out an antenna coefficient value from the storage unit based on data corresponding to the data, and a digital display unit that displays the antenna coefficient value obtained by the arithmetic processing unit, The indicator is designed to simultaneously display the indicated value and the indicated value necessary to determine the electric field strength.

(Function) Regarding the antenna coefficient values determined according to the type of antenna and the frequency characteristics of the antenna, the antenna coefficient values of a plurality of predetermined antennas are each stored in the storage unit, and one of the antenna coefficient values of a certain frequency band is stored.
The reception output received by the reception unit via two antennas is displayed in analog on the analog indicator, and at the same time, the arithmetic processing unit stores data from the storage unit based on the type of antenna and the frequency corresponding to the reception frequency sent from the reception unit. Since the antenna coefficient value obtained for each frequency is displayed on the digital display section according to the frequency characteristics of the read antenna, even discontinuous waves can be visually recognized by the analog display, and it can be easily determined from the visually recognized value and the digitally displayed value. Moreover, the electric field strength can be read accurately.

(Example) Hereinafter, an example of the present invention will be described with reference to the drawings. In the figure, reference numeral 11 denotes an antenna having at least one antenna coefficient within a specific frequency band, and this antenna 11 is connected to an antenna connection section 12 having a switch or the like. This connection 12 has antennas 11 with various frequency bands or different types of antennas 1.
It is assumed that the first class is connected. Switching information at this connection section is automatically sent to the arithmetic processing section 17. 14 is a receiving section having a frequency conversion circuit, an amplification circuit, a detection circuit, etc.; 15 is an analog indicator that displays the reception output of the receiving section 14; and 16 is an antenna coefficient k ₀₁ to k using the receiving frequency and the type of antenna as parameters. _0o ′, k ₁₁ ~k _1o ′…
This is a storage unit that stores ... in a matrix. For example, the unique reception frequency for the antenna at address 0 is the antenna coefficient k ₀₁ ′, corresponding to ₁ , ₂ ..., _o .
k ₀₂ ′..., k _0o are stored, and antenna coefficients k ₁₁ ′, k ₁₂ ′..., k 1o are similarly stored corresponding to the unique reception frequencies ₁ , ₂ ..., _o for the antenna at address _1. be done. 17 is an arithmetic processing unit, and a storage unit 1
It has a function of reading out the antenna coefficient value of a specific frequency stored in the antenna 6 based on the reception frequency of the type of antenna 11 used. 18 is a digital display unit that displays digital data as a result of arithmetic processing.

Next, the operation of the device configured as above will be explained. For example, connect antenna 11 at address 1 to connection section 1.
2, address 1 is sent to the arithmetic processing unit 17 as antenna type information. This address 1
A signal received by the antenna 11 corresponding to , for example, is received by the receiving section 14 as receiving frequency ₁ , and its receiving output V is displayed on the analog indicator 15 . On the other hand, the receiving unit 14 receives received frequency information.
₁ is sent to the arithmetic processing unit 17. This arithmetic processing unit 17 receives the reception frequency information ₁ and the antenna type information, sends address information to the storage unit 16, controls the storage unit 16, and controls the storage unit 16 to address the address corresponding to the frequency ₁ stored in advance. Read out the antenna coefficient k ₁₁ of 1. This antenna coefficient k ₁₁ is displayed on the digital display section 18. Therefore, by reading the displayed value k (k ₁₁ ), the above-mentioned formula (V+
If calculation is performed artificially based on k), the electric field strength E can be determined accurately. When the type of antenna 11 is changed, the electric field strength E can be determined in the same manner as described above.

Therefore, according to the configuration of the embodiment as described above,
A large number of antenna coefficients are stored in advance in the storage unit 16, and the type of antenna 11 and reception frequency ( ₁ to ₂ )
The antenna coefficient read out from the storage unit 16 according to the command from the calculation unit 17 is displayed.
This eliminates the complexity of managing antenna coefficient tables as in the past, eliminates the problems of losing or misreading antenna coefficient tables, and eliminates the need for particularly complicated equipment such as function generators. Desired digital data can be displayed.
In addition, with conventional digital processing and display methods, it was difficult to visually confirm measured values in cases such as rapidly changing discontinuous waves, but with analog indicators as in this application, the received output can be clearly seen.

Note that the above embodiment uses an analog indicator to display the reception level, but if the reception level is so high that the indicator swings out, it is necessary to install a high-frequency attenuator on the input side of the receiving section 14, or to install a high-frequency attenuator on the input side of the receiver 14. If there is no attenuator and an intermediate frequency attenuator is provided in the receiver 14, or if there is a high frequency attenuator and an attenuator in the receiver 14, the attenuation amount information of each attenuator can be added to the reading of the analog indicator. Since this can be used as the reception level, it can be applied in the same way as the above embodiment.
In addition, the present invention can be modified and implemented in various ways without departing from the gist thereof.

(Effects of the invention) As detailed above, according to the invention, since the analog indicator is used to indicate the reception output in analog, even discontinuous waves can be accurately visually recognized, and a large number of antenna coefficients can be stored in advance in the memory. Since it is memorized and read out according to the antenna frequency and displayed digitally, problems such as the complexity of conventional management, loss of antenna coefficient tables, and reading errors are eliminated. Due to the physical characteristics of the needle, there is a delay in tracking the needle, resulting in an average pointer display, so by combining it with a digital display, more functional display and measurement is possible, and overall the electric field strength can be adjusted with a simple configuration. It is possible to provide an electric field strength measuring device that can measure accurately.

[Brief explanation of the drawing]

The figure is a configuration diagram showing an embodiment of an electric field strength measuring device according to the present invention. 11...Antenna, 12...Connection part, 14...
Receiving section, 15... Analog indicator, 16... Storage section, 17... Arithmetic processing section, 18... Digital display section.

Claims (1)

[Claims for Utility Model Registration] A storage unit 16 that stores antenna coefficient values determined in advance according to the type of antenna 11 and the frequency characteristics of the antenna, respectively, of a plurality of antennas; a receiving section 14 that receives a signal taken out through an antenna; an indicator 15 that displays an analog reception output of the receiving section; an arithmetic processing unit 17 that reads antenna coefficient values from the storage unit;
and a digital display section 18 that displays the antenna coefficient value obtained by the arithmetic processing section, and simultaneously displays display values and indicated values necessary for determining the electric field strength on the digital display section and the analog indicator. An electric field strength measuring device characterized in that: