JP2019164061A - Long-period noise capturing performance evaluation system and method, and comb generator - Google Patents

Abstract

To provide a long-period noise capturing performance evaluation system capable of evaluating a long-period noise capturing performance by an actual measurement, and to provide a comb generator capable of generating a reference signal for simulating a long-period noise by the evaluation system.SOLUTION: When observation time of a receiver 5 included in an EMC measurement system is D, a burst including a plurality of pulses having a pulse period tof a reciprocal of a spectrum peak interval 1/tis continuously transmitted at a burst period T in which T is larger than D from a comb generator 21 for generating a reference signal, the reference signal is measured for a plurality of times by the EMC measurement system, and it is measured whether the EMC measurement system captures a long-period noise normally from a ratio of the number of reception times of the reference signal to the number of measurement times.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a long-period noise capturing performance evaluation system and method in an EMC (electromagnetic compatibility) measurement system, and a comb generator usable in the evaluation system and method.

  FIG. 12 shows an example of a radiated emission measuring apparatus in EMC measurement. The turntable 1 is disposed on the floor surface of the anechoic chamber, the antenna 3 is supported by the antenna positioner 2 at a height set from the floor surface, 1 includes a mechanism control unit 4 that controls the rotation of the antenna 1 and the height of the antenna 3 via the antenna positioner 2, and a receiver 5. An EUT (Equipment Under Test) 7 that is a device under test, a turntable 1 on which the EUT (Equipment Under Test) 7 is placed, an antenna 3 and an antenna positioner 2 are arranged in an anechoic chamber or an open site. The mechanism control unit 4 and the receiver 5 are arranged in a measurement room outside the anechoic chamber or a measurement room laid out under the ground plane in the open test site so as not to affect the measurement.

  In the radiated emission measurement that measures the electromagnetic wave (radiated emission) radiated by the EUT in the EMC measurement, the radiated emission from the EUT is selected from the radiated emission from the EUT by the first pre-scan. . Prescan uses a receiver, antenna positioner, turntable, etc. to identify the approximate frequency and maximum radiation direction of the jamming that may exceed the tolerance.

  Conventionally, in prescan, a spectrum analyzer has been mainly used as the receiver 5 of FIG. The spectrum analyzer performs frequency sweep and measures the frequency characteristics of noise radiated from the EUT 7. Therefore, if the maximum radiation position is specified by moving the antenna position via the antenna positioner 2 while taking sufficient dwell time (observation time) for each frequency, the measurement time becomes very long, which is not practical. Therefore, it was difficult to set a sufficient dwell time, it was difficult to detect anything other than short-term continuous interference waves, and the capture of long-period noise and pulsed noise depended on the experience level of the measurer. .

  In recent years, introduction of measuring instruments using time domain scanning has progressed as receivers for EMC measurement. A time domain receiver or a real time spectrum analyzer basically obtains data in a wide frequency domain by performing FFT (Fast Fourier Transform) on a signal sampled in the time domain. Therefore, in the spectrum analyzer, it has become possible to obtain a result equivalent to the measurement result obtained by taking the dwell time for each measurement frequency from one time-domain sampling data. For this reason, it has become practical to perform a pre-scan with a long residence time, and it has become possible to capture long-period noise that has been difficult to capture.

  The comb generator is an oscillator that is used for generating a reference signal for evaluating frequency characteristics in a start-up inspection of a test facility for radiated emission measurement. In the radiation emission measurement, the frequency band of the measurement standard is determined to be 30 MHz-1 GHz, 1 GHz-6 GHz, or the like, for example. One of the characteristics of the comb generator is that it has a wide frequency band so that these measurement bands can be evaluated collectively. Further, in the band, it has a comb-like spectrum of constant steps such as 1 MHz and 10 MHz. In the evaluation and inspection of a test facility for radiated emission measurement, a signal radiated from a comb generator is received, and an amplitude value of each spectrum in a frequency band is measured to perform evaluation or abnormality detection.

Looking at the signal transmitted from a conventional comb generator in the time domain are transmitted continuously without pulse width τ is interrupted at a predetermined period t ₁ as shown in FIG. 13. Period t ₁ is the inverse of the spectral interval in the frequency domain. For example, the pulse transmission period t ₁ of a generally used 1 MHz, 10 MHz step comb generator is 1 μs and 100 ns, respectively. In addition, the pulse width τ and the spectral bandwidth in the frequency domain are also inversely proportional to each other. Specifically, each harmonic frequency is n times (n: natural number) the fundamental frequency 1 / t ₁ , and the amplitude of each harmonic frequency is proportional to the sampling function Sa (nπτ / t ₁ ). If the pulse transmission cycle t ₁ is constant, the coefficient of the variable n of the sampling function Sa (nπτ / t ₁ ) becomes smaller as the pulse width τ becomes smaller. Therefore, since the change of the sampling function with respect to n extends as the pulse width τ is smaller, it has a higher frequency component.

US Pat. No. 5,594,458 discloses a technical description of a general comb generator itself and a method for calibrating EMC measurement equipment using the comb generator. Japanese Patent Laid-Open No. 2005-49200 Patent Document 2 is a short pulse generation circuit, and shows a technique for shaping a waveform so as to shorten a pulse width by combining a transistor and a delay element.

  When an EMC measurement system incorporating a time domain receiver capable of capturing long-period noise as described above is constructed, it is verified whether long-period noise can be captured as designed over the entire frequency band specified by the measurement standard. There is a need to do. In particular, in the case of long-period noise, if the frequency of occurrence itself is low and noise cannot be captured due to an abnormality in the EMC measurement system, it is difficult to notice the occurrence of abnormality compared to short-period noise. Therefore, it is desirable to confirm whether long-period noise has been captured as expected by actual measurement.

  However, when verifying the long-period noise capturing performance, a conventional comb generator cannot be used as a reference signal. As described above, a conventional comb generator generally transmits pulses continuously in a cycle of the order of ns and μs. Therefore, a noise having a cycle of ms order or more that is generally regarded as a long cycle noise. As an alternative, it cannot be used for evaluation.

  In view of the above problems, the present invention is a long-period noise capturing performance evaluation system and method capable of evaluating long-period noise capturing performance by actual measurement, and long-period noise is simulated by the evaluation system and method. An object of the present invention is to provide a comb generator capable of generating a reference signal.

A first aspect of the present invention is a long-period noise capturing performance evaluation system in an EMC measurement system having an antenna and a receiver to which a reception signal of the antenna is input,
Comb generator for generating a reference signal, and a received data determination device to which an output signal of the receiver is input,
When the observation time of the receiver is D (s), the comb generator generates, as the reference signal, a pulse having a pulse period t ₁ (s) that is a reciprocal of a desired spectral peak interval 1 / t ₁ (Hz). A burst including a plurality is continuously transmitted in a burst period T (s) where T> D,
The EMC measurement system performs the measurement of the reference signal a plurality of times. In the received data determination device, the EMC measurement system normally generates long-period noise from the ratio of the number of times the reference signal is received to the number of times the measurement is performed. It is characterized by determining whether it has captured.

In the first aspect, the comb generator has, as the reference signal, a pulse having a pulse width of 1 (ns) or less per burst k × D / t ₁ +1 (where the coefficient k is a positive value less than 1)
It is recommended to transmit bursts including the following integers.

  The received data determination device compares the ratio of receiving the reference signal with an expected value in a range of not less than D / T and not more than (1 + k) × D / T. It may be determined whether noise is captured.

A second aspect of the present invention is a long-period noise capturing performance evaluation method in an EMC measurement system,
When the observation time of the receiver included in the EMC measurement system is D (s),
A burst including a plurality of pulses having a pulse period t ₁ (s), which is a reciprocal of a desired spectral peak interval 1 / t ₁ (Hz), from a comb generator that generates a reference signal is a burst period T (s ) To send continuously,
The EMC measurement system performs the measurement of the reference signal a plurality of times, and determines whether the EMC measurement system normally captures long-period noise from the ratio of the number of times the reference signal is received to the number of times the measurement is performed. It is characterized by determining.

In the second mode, a pulse having a pulse width of 1 (ns) or less per burst from the comb generator as the reference signal is k × D / t ₁ +1 (where the coefficient k is a positive value less than 1).
It is recommended to transmit bursts including the following integers.

  Whether the EMC measurement system normally captures long-period noise by comparing the ratio of receiving the reference signal with an expected value in the range of (D + T) to (1 + k) × D / T. It is good to judge.

  The coefficient k may be a numerical value in which the coefficient k is greater than 0 and 0.1 or less.

A third aspect of the present invention is a comb generator, wherein a burst including a plurality of pulses having a pulse period t ₁ (s) that is a reciprocal of a desired spectral peak interval 1 / t ₁ (Hz) is used as a reference signal. The transmission is continuously performed in a burst cycle T (s) where T> D.

It is preferable that the number of pulses having the pulse period t ₁ is an integer of (T / t ₁ ) −1 or less per burst.

  It should be noted that any combination of the above-described constituent elements, and those obtained by converting the expression of the present invention between methods and systems are also effective as aspects of the present invention.

  According to the long-period noise capturing performance evaluation system and method according to the present invention, it is possible to evaluate the long-period noise capturing performance by actual measurement. Further, according to the comb generator of the present invention, it is possible to generate a reference signal that simulates long-period noise suitable for use as a reference signal generator in a long-period noise capturing performance evaluation system.

The block diagram which shows embodiment of the long-period noise capture performance evaluation system and method in the EMC measuring system which concerns on this invention. The wave form diagram of the reference signal (time domain display) which the comb generator as a reference signal generator in an embodiment transmits. The spectrum figure of the reference signal (frequency domain display) which a comb generator transmits. In embodiment, explanatory drawing in case the burst length of a reference signal is very short compared with observation time. Explanatory drawing when the burst length of a reference signal cannot be disregarded compared with observation time in embodiment. The power spectrum figure of the single pulse of pulse width 0.8ns. The time waveform figure of the reference signal of the burst length 100ns which can be used in embodiment. The power spectrum figure of the reference signal of FIG. FIG. 6 is a time waveform diagram of a reference signal having a burst length of 500 ns that can be used in the embodiment. The power spectrum figure of the reference signal of FIG. The block diagram of the comb generator in embodiment. The block diagram which shows an example of a radiation emission measuring system. The wave form diagram of the reference signal (time domain display) of the conventional comb generator.

  Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the drawings. In addition, the same code | symbol is attached | subjected to the same or equivalent component, member, process, etc. which are shown by each drawing, and the overlapping description is abbreviate | omitted suitably. In addition, the embodiments do not limit the invention but are exemplifications, and all features and combinations thereof described in the embodiments are not necessarily essential to the invention.

  FIG. 1 shows an example of an EMC measurement system 10 according to an embodiment of the present invention, which is supported at a height set from the floor by a turntable 1 and an antenna positioner 2 arranged on the floor of an anechoic chamber. An antenna 3 and a receiver 5 that receives a reception signal of the antenna 3 (a reception signal is input) are provided. An EUT (Equipment Under Test) which is a device under test, a turntable 1 on which the EUT (Equipment Under Test) is mounted, an antenna 3 and an antenna positioner 2 are arranged in an anechoic chamber or an open site. The receiver 5 is arranged in a measurement room outside the anechoic chamber or in a measurement room laid out under the ground plane in the open test site so as not to affect the measurement. Although not shown, a mechanism control unit for controlling the rotation of the turntable 1 and the height of the antenna 3 via the antenna positioner 2 is provided. The operations of the turntable 1, the antenna positioner 2, the receiver 5 and the like are controlled by a predetermined measurement control program 8. The receiver 5 is, for example, a time domain receiver, a real-time spectrum analyzer, a digital storage oscilloscope, or the like.

  A long-period noise capturing performance evaluation system 20 for verifying the long-period noise capturing performance of the EMC measuring system 10 is added to the EMC measuring system 10. The long-period noise capturing performance evaluation system 20 receives a comb generator 21 as a reference signal generator that radiates a reference signal to the antenna 3 and received data obtained by the execution of the measurement control program 8 (the received data is input). And a received data judging device 22 for judging received data.

As a reference signal, a comb generator 21 that transmits a periodic burst wave (burst pulse) shown in FIG. 2 in the time domain is used. Here, in the periodic burst wave of FIG. 2, the burst, which is a short-cycle pulse group of the pulse period t ₁ (s), is continuously (repeated) with a long period (burst period = reference signal generation period T). It is a generated waveform. The number of pulses per burst is set to an integer equal to or less than (T / t ₁ ) −1 at the pulse period t ₁ . By providing a period in which a pulse of at least one pulse period or more is not transmitted between bursts, a time domain signal is divided for each burst. The pulse width τ of the pulse having the pulse period t ₁ is, for example, 1 ns or less, and when the observation time of the receiver 5 is D (s), the number of short-cycle pulses per burst is, for example, 0.1 × (D / t ₁ ) +1. In this case, in the frequency domain, the reference signal is a signal having a bandwidth of 1 GHz or more with a spectrum peak interval 1 / t ₁ (Hz) as shown in FIG. 3 (the frequency spectrum does not zero cross until 1 GHz). Therefore, for example, when the measurement standard is 30 MHz-1 GHz, it is possible to collectively evaluate the frequency characteristics of the entire band. 2 is regarded as one long-period noise period, noise is generated for each period T in the time domain by considering the generation period {reference signal generation period T (s)} of one burst shown in FIG. It can be treated as a signal simulating long-period noise.

  Consider a case in which the observation time is set to D and the reference signal transmitted from the comb generator 21 is measured for the receiver 5 incorporated in the EMC measurement system 10 to be evaluated. During the observation time D, the receiver 5 samples the time signal at the set sampling period. Then, the frequency domain characteristics of the necessary band are obtained by performing FFT on the time signal.

  First, consider the case where the burst length of the reference signal is set to be negligibly short compared to the burst period (= reference signal generation period T) and the observation time D of the receiver 5 as shown in FIG. When this receiver 5 receives a control command from the measurement control program 8 of the EMC measurement system 10 and starts observation at an arbitrary time, the expected value of the probability of receiving the reference signal transmitted from the comb generator 21 is D / T. This is because the comb generator 21 always transmits the reference signal at the period T, so that the probability that the comb generator 21 transmits the reference signal during the observation time D, in other words, the probability that the receiver 5 receives the reference signal. Becomes D / T. The EMC measurement system 10 incorporating the receiver 5 observes the reference signal a sufficient number of times, and the reception data determination device 22 determines whether or not the reception data is received every measurement frequency and peak frequency by the reception data determination device 22. When the probability is calculated, the reception probability of the reference signal converges to D / T when the evaluation target EMC measurement system is correctly constructed. On the contrary, when the reception probability deviates significantly from D / T, it can be detected that there is some abnormality. When performing the above evaluation, the measurement control program 8 of the EMC measurement system 10 to be evaluated controls not only the receiver 5 but also other devices included in the system such as the turntable 1 and the antenna positioner 2, and received data. By evaluating the received data acquired while performing the same processing as in actual EMC measurement, such as the above calculation, by the received data determination device 22, it is possible to evaluate the long-period noise capturing performance in actual use.

  Although the case where the burst length is negligible compared with the observation time D has been described so far, in practice, the reference signal burst has a length. Therefore, when the burst length B of the reference signal is not negligible compared to the observation time D as shown in FIG. 5, a case where the burst is located at the end of the observation time D occurs. In that case, the amplitude value of the received signal decreases as compared with a state in which the amplitude is completely within the observation time. When the burst length is B, the probability that the burst length B is 100% within the observation time D is (D−B) / T, and the probability that a part of the burst length B is within the observation time D is 2B / T.

In the present embodiment, when the number of pulses per burst is k × (D / t ₁ ) +1 (however, a positive number less than the coefficient k: 1, preferably 0.1 or less), the burst length B in FIG. Is limited to the observation time D × k. The probability that a part or all of the burst length B enters the observation time D is (1 + k) D / T. In addition, the probability that only a part of the burst falls within the observation time is 2Dk / T. When a part of the burst length falls within the observation time D, the amplitude value of the received signal obtained by the receiver 5 varies in proportion to the length of the time when the observation time D is entered. Therefore, the expected value is changed by adjusting the threshold level for determining whether or not the reference signal is received by the reception data determination device 22 that receives the reception signal. For example, when the threshold level is set in the vicinity of the level where there is no received signal (the state where no reference signal is received), the expected value is the maximum (1 + k) D / T. When the threshold level is set in the vicinity of the level when 100% of the burst length falls within the observation time, the expected value is (1-k) D / T.

For example, the case where the coefficient k is selected to be 0.1 or less will be specifically described. That is, when the number of pulses per burst is 0.1 × (D / t ₁ ) +1 or less, the burst length B in FIG. 5 is limited to 10% or less of the observation time D. When the maximum burst length is 0.1D, the probability that a part or all of the burst length B enters the observation time D is 1.1 × D / T. Further, the probability that only a part of the burst falls within the observation time is 0.2 × D / T or less. When a part of the burst length falls within the observation time D, the amplitude value of the received signal obtained by the receiver 5 varies in proportion to the length of the time when the observation time D is entered. Therefore, the expected value is changed by adjusting the threshold level for determining whether or not the reference signal is received by the reception data determination device 22 that receives the reception signal. For example, when the threshold level is set in the vicinity of a level where there is no received signal (a state where no reference signal is received), the expected value is 1.1 × D / T, which is the maximum. When the threshold level is set in the vicinity of the level when 100% of the burst length enters the observation time, the expected value is 0.9 × D / T. However, in any case, the determination of whether or not the reference signal is received is likely to be affected by noise, which is not preferable. Therefore, preferably, if the S / N ratio of the received signal is sufficient, a part of the received signal is reduced to the observation time by shortening the burst length as much as possible compared to the reference signal generation period and the observation time of the receiver. It is desirable to reduce the rate of entering. If the rate at which a part of the received signal enters the observation time is sufficiently small, it is considered that the expected value of the probability of receiving the reference signal may be regarded as D / T without adjusting the threshold level.

  In view of the above points, the coefficient k is preferably set to 0.1 or less. If the coefficient k is greater than 0.1, the expected value depending on the threshold level tends to fluctuate, which is not preferable.

<Example of reference signal transmission waveform>
An example of the transmission waveform of the reference signal generated by the comb generator 21 will be described with reference to FIGS. A reference signal transmission waveform when a bandwidth of 1 GHz, a spectrum peak interval of 100 MHz, and a reference signal generation period (burst period) of 1 ms are described as desired reference signals.

  First, in order to output the desired reference signal, the setting of each parameter for the transmission waveform in the time domain will be described. First, considering the pulse width τ of a short-cycle pulse included in a burst, in the time domain, the Fourier transform of a single pulse wave represented by a rectangular function becomes a sinc function. If the pulse width τ is set to 1 ns or less, the frequency spectrum does not zero cross up to 1 GHz. FIG. 6 shows the power spectrum of a single pulse when the pulse width τ is 0.8 ns. When the power spectrum value near 1 GHz is compared with that near DC, the value is reduced by about 10 dB.

Next, considering the pulse period t ₁ of the short-period pulse, the pulse period t ₁ is 10 ns because it is the reciprocal of the desired spectral peak interval of 100 MHz. Further, since the number of transmission pulses per burst is set to 0.1 × (burst cycle / pulse cycle) +1 or less, in this example, the number of pulses is set to 10,001 or less. However, as described above, in the pulse capture performance evaluation, it is desirable that the burst length is short because it is desired to reduce the proportion of the burst length that falls within the observation time. Therefore, FIG. 7 shows a time domain waveform when the number of pulses is set to 11 and the burst length is set to 100 ns. FIG. 8 shows the power spectrum of the waveform of FIG.

  FIG. 9 shows a time waveform when the number of pulses is set to 51 and the burst length is set to 500 ns as a comparison with FIG. FIG. 10 shows the power spectrum of this waveform.

  The spectral peak intervals of the power spectra in FIGS. 8 and 10 are both the desired 100 MHz. The shape of the envelope of the spectrum peak is equal to the spectrum shape of the single pulse shown in FIG. 6, and the power spectrum value at 1 GHz is about 10 dB lower than the value at DC. Therefore, a desired reference signal can be obtained by transmitting the time waveform shown in FIG. 7 or FIG. 9 at a period of 1 ms. Further, comparing the power spectrum levels at the respective spectrum peaks in FIGS. 8 and 10, the number of pulses per burst is increased in FIG. 10 by about 13 dB. As described above, when used for the evaluation of the pulse capturing performance, it is desirable that the burst length is short. However, for example, when the reference signal from the comb generator 21 is propagated for a long distance and used for evaluation, the S / N ratio may be small. In such a case, the S / N ratio can be improved by increasing the number of pulses per burst as necessary.

<Evaluation of noise capture performance in long-period noise capture performance evaluation system>
As shown in FIG. 1, a long-period noise capturing performance evaluation system 20 is added to the EMC measurement system 10. Assuming long-period noise with a period of 1 ms, the EMC measurement system 10 has a receiver 5 with an observation time of 100 μs. In the following, an example in which the evaluation of long-period noise capturing performance is performed will be described.

  As described with reference to FIGS. 4 and 5, if the burst length B is short, the probability of the end of the observation time D of the receiver 5 decreases. Therefore, it is preferable that the burst length B is short. A case will be described in which the burst length B is set to 100 ns, which is 0.1% of the observation time D (in the case of the reference signal in FIGS. 7 and 8).

  Under this condition, when the reference signal transmitted from the comb generator 21 is observed so that the number of times is sufficient, the approximate expected value for receiving the reference signal is observation time / burst period = 0.1, which is about 10%. Can be received with a probability of. However, as described above, when the burst length B is finite, the burst may reach the end of the observation time, and the reception level may vary. In this example, the probability that a part of the burst length falls within the observation time is 0.02% from 2 × burst length / burst period. In addition, the probability that the burst length is 100% within the observation time is 9.99% from (D−B) / T, which is close to the expected value of 10% when the burst length can be ignored. In this case, the probability of receiving an amplitude value other than the noise level and the amplitude value when the burst is 100% within the observation time is sufficiently low, 0.02%. The influence of the level setting on the expected value of the capture rate is reduced. For example, in order to reduce the influence of noise, it is considered that a value of 10% can be applied to the expected value of the capture rate even when the amplitude is set to half of the amplitude when the burst is 100% within the observation time.

  Further, as described above, when the S / N ratio of the received reference signal is low, the S / N ratio is improved by increasing the burst length B and increasing the number of pulses per burst. However, when the burst length B is set long, the probability that a part of the burst length B falls within the observation time increases. As an example, the case where the burst length B is increased to five times the previous example and the burst length B is set to 500 ns, which is 0.5% of the observation time D (in the case of the reference signal in FIGS. 9 and 10) will be described. To do. In this case, the probability that a part of the burst length B falls within the observation time D is also 5%, 0.1% higher than 2B / T. The probability that the burst length B is 100% within the observation time D is reduced to 9.95% from (D−B) / T. In this case, if the threshold level is set to half of the amplitude value when the burst is 100% within the observation time as in the previous example, the number of reception level signals close to the threshold level will increase. , Susceptible to noise.

<Hardware configuration of comb generator as reference signal generator>
FIG. 11 shows a hardware configuration example of the comb generator 21 that outputs a burst wave having a pulse width of 1 ns or less and an arbitrary period and the number of pulses. The comb generator 21 has a burst wave generation circuit unit 31 that periodically generates a desired burst wave with a pulse having a pulse width wider than 1 ns, and the pulse width τ of the burst wave output from the burst wave generation circuit unit 31 is 1 ns or less. And a waveform shaping circuit unit 32 for shaping the waveform. As the burst wave generation circuit unit 31, for example, when an FPGA (Field-Programmable Gate Array) that operates at 200 MHz, which is a type of logic circuit, is used, the clock cycle is 5 ns, so that an arbitrary logic waveform can be generated with a time resolution of 5 ns. Can occur. The waveform shaping circuit unit 32 can be configured by a known technique such as Patent Document 2.

As a reference signal from the comb generator 21, a pulse of the pulse period t ₁ shown in FIG. 2, for example in the time domain when transmitting a periodic burst waves containing a plurality for each burst, spectral peak interval as in the frequency domain are shown in Figure 3 It becomes a signal having a bandwidth of 1 GHz or more at 1 / t ₁ . The number of pulses having a pulse period t ₁ is set so as to be an integer equal to or less than (T / t ₁ ) −1 per burst. By providing a period in which a pulse of at least one pulse period or more is not transmitted between bursts, a time domain signal can be divided for each burst, and a long-period noise is generated during one period. It is possible to simulate long-period noise (for example, noise having a period on the order of ms) (the burst period is the sum of the burst length and the time until the next burst arrives).

<Evaluation method of EMC measurement system>
The long-period noise capturing performance evaluation method of the present invention can be used for evaluation of a radiation emission measurement system as shown in FIG. Here, instead of the EUT 7 as the device under test, a comb generator 21 as a reference signal generator is installed, and a burst wave reference signal is transmitted. Repeat the field strength measurement a sufficient number of times with the radiated emissions measurement system. The actual value of the capture rate is calculated from the number of times the reference signal is captured by the receiver 5 and is compared with the expected value calculated from the burst period T of the reference signal and the observation time D of the receiver 5, thereby radiating emissions. Verify that the entire measurement system is properly controlled.

  According to the present embodiment, the following effects can be achieved.

(1) When the observation time of the receiver 5 included in the EMC measurement system 10 is D, a pulse having a pulse period t _{1 which} is a reciprocal of a desired spectral peak interval 1 / t ₁ is output from a comb generator 21 that generates a reference signal. The number of times that the reference signal is received with respect to the number of times the measurement is performed by the EMC measurement system 10 performing the measurement of the reference signal a plurality of times. It is possible to determine whether or not the EMC measurement system normally captures long-period noise from the ratio. For this reason, it is possible to evaluate long-period noise capturing performance by actual measurement.

(2) In the reference signal, a burst pulse including a pulse having a pulse width of 1 ns or less and an integer number of pulses of 0.1 × D / t ₁ +1 or less per burst is continuously transmitted repeatedly, and the reference signal is received. When the ratio is compared with an expected value in the range of not less than D / T and not more than 1.1 × D / T to determine whether the EMC measurement system 10 is normally capturing long-period noise, the burst length B becomes shorter than the observation time D, and the fluctuation of the expected value due to the threshold level setting can be reduced.

(3) The comb generator 21 transmits a burst wave as a reference signal, and is set so that a short-cycle pulse with a pulse period t ₁ is included in an integer of (T / t ₁ ) −1 or less per burst. Thus, it is possible to provide a period during which at least one pulse period or more is not transmitted between bursts, and it is possible to classify a signal in the time domain for each burst. Long-period noise can also be simulated by considering it as noise generated in the meantime.

  The present invention has been described above by taking the embodiment as an example. However, it is understood by those skilled in the art that various modifications can be made to each component and each processing process of the embodiment within the scope of the claims. By the way. Hereinafter, modifications will be described.

The present invention can be applied to various EMC measurement systems by changing the pulse width τ, the period t _1, and the burst period T of a short period pulse according to the measurement frequency range.

  As the circuit configuration of the comb generator according to the present invention, any configuration can be adopted as long as a target burst wave can be generated.

1 Turntable 2 Antenna Positioner 3 Antenna 4 Mechanism Control Unit 5 Receiver 7 EUT
8 Measurement Control Program 10 ECM Measurement System 20 Long-Period Noise Capture Performance Evaluation System 21 Com Generator 22 Received Data Determination Device 31 Burst Wave Generation Circuit Unit 32 Waveform Shaping Circuit Unit

Claims (10)

A long-period noise capturing performance evaluation system in an EMC measurement system having an antenna and a receiver to which a reception signal of the antenna is input,
Comb generator for generating a reference signal, and a received data determination device to which an output signal of the receiver is input,
When the observation time of the receiver is D (s), the comb generator generates, as the reference signal, a pulse having a pulse period t ₁ (s) that is a reciprocal of a desired spectral peak interval 1 / t ₁ (Hz). A burst including a plurality is continuously transmitted in a burst period T (s) where T> D,
The EMC measurement system performs the measurement of the reference signal a plurality of times. In the received data determination device, the EMC measurement system normally generates long-period noise from the ratio of the number of times the reference signal is received to the number of times the measurement is performed. A long-period noise capturing performance evaluation system that determines whether or not a signal is captured. In the comb generator, as the reference signal, a pulse having a pulse width of 1 (ns) or less is per burst k × D / t ₁ +1 (where the coefficient k is a positive value less than 1)
The long-period noise capturing performance evaluation system according to claim 1, wherein bursts including the following integers are transmitted.   The received data determination device compares the ratio of receiving the reference signal with an expected value in a range of not less than D / T and not more than (1 + k) × D / T. The long-period noise capturing performance evaluation system according to claim 2, wherein it is determined whether or not noise is captured.   The long-period noise capturing performance evaluation system according to claim 2 or 3, wherein the coefficient k is a numerical value greater than 0 and 0.1 or less. A method for evaluating long-period noise capturing performance in an EMC measurement system, comprising:
When the observation time of the receiver included in the EMC measurement system is D (s),
A burst including a plurality of pulses having a pulse period t ₁ (s), which is a reciprocal of a desired spectral peak interval 1 / t ₁ (Hz), from a comb generator that generates a reference signal is a burst period T (s ) To send continuously,
The EMC measurement system performs the measurement of the reference signal a plurality of times, and determines whether the EMC measurement system normally captures long-period noise from the ratio of the number of times the reference signal is received to the number of times the measurement is performed. A long-period noise capturing performance evaluation method for determining. From the comb generator, as the reference signal, a pulse with a pulse width of 1 (ns) or less per burst k × D / t ₁ +1 (where the coefficient k is a positive value less than 1)
6. The long-period noise capturing performance evaluation method according to claim 5, wherein bursts including the following integers are transmitted.   Whether the EMC measurement system normally captures long-period noise by comparing the ratio of receiving the reference signal with an expected value in the range of (D + T) to (1 + k) × D / T. The long-period noise capturing performance evaluation method according to claim 6, wherein:   The long-period noise capturing performance evaluation method according to claim 6 or 7, wherein the coefficient k is a numerical value that is greater than 0 and less than or equal to 0.1. As a reference signal, a burst including a plurality of pulses having a pulse period t ₁ (s) that is a reciprocal of a desired spectral peak interval 1 / t ₁ (Hz) is continuously generated at a burst period T (s) where T> D. Com generator to send. The pulse of the pulse period _{t 1} is, per burst _{(T /} t 1) -1 include an integer number of following comb generator according to claim 14.