JPH0549063B2 - - Google Patents

Description

[Detailed description of the invention] (Industrial application field) The present invention relates to a filter inspection device.

(Prior art) For example, in order to detect whether a filter such as a bandpass filter maintains its filter characteristics, it is common practice to use a sine wave signal of its center frequency and frequencies before and after it. It is said that FIG. 6 shows the configuration of the conventional example, in which 1 is a filter circuit to be detected, 2 is an input terminal to which a filter input is applied, and 3 is an output terminal of the filter circuit 1.

For inspection, the center frequency of filter circuit 1
A sine wave oscillator 4 is prepared which outputs sine wave check signals of three types of frequencies: f 0 and frequencies f ₁ and f ₂ before and after f ₀ . Reference numeral 5 denotes a changeover switch which selectively switches between the terminal 6 to which each of the above inspection signals is applied and the terminal 7 to which the filter input is applied from the input terminal 2, and applies this to the filter circuit 1.

8 is a conversion circuit that converts the output from the filter circuit 1 into a DC voltage; ₉ is a reference value circuit; when the filter circuit ₁ to be detected is healthy _, Signals E ₀ , E ₁ , and E ₂ having the same magnitude as the output signal when the wave signal is applied are output as reference signals. Reference numeral 10 denotes a change-over switch which is interlocked with the change-over switch 5 and selectively switches between the terminal 11 to which each of the reference signals is applied and the terminal 12 to which the output from the conversion circuit 8 is applied, and applies this to the comparison circuit 13.

The comparison circuit 13 receives each of the reference signals and the conversion circuit 8.
It is determined whether this converted output is within a preset range including the reference signal given from the reference value circuit 9. If the conversion output exceeds this range, the filter circuit 1 is determined to be abnormal and outputs an output.

In the above configuration, when the filter circuit 1 is not inspected, the changeover switches 5 and 10 are switched to the terminals 7 and 12, respectively. At this time, the filter circuit 1 operates on the input signal applied to the input terminal 2. During inspection, changeover switches 5 and 10 are switched to terminals 6 and 11 in order. Each time, the comparison circuit 13 compares the reference signal from the reference value circuit 9 with the output of the conversion circuit 8 for the inspection signal. When the output from the conversion circuit 8 exceeds a predetermined width with respect to the reference signal,
It is determined that the filter circuit 1 is abnormal.

In this way, it is possible to inspect the filter circuit 1, but as a practical matter, an oscillation circuit that can freely oscillate signals of three types of frequencies is required, and moreover, it is required that it be a sine wave. . If this type of sine wave oscillation circuit were to oscillate stably in both frequency and amplitude, its configuration would be extremely complicated and expensive.

Another method has been proposed in which a square wave signal is applied to a filter for the purpose of testing the frequency characteristics of the filter, but this proposed method passes the rising or falling portion of the square wave signal, Passing waveform at that time (transient response waveform)
is compared with a standard waveform when the filter is normal.

However, with this test method, pattern recognition of the response waveform is required to determine the quality of the filter, which requires evaluation equipment with complex circuit configurations, such as pattern recognition equipment and waveform analysis equipment (fast Fourier transform equipment). .

(Problems to be Solved by the Invention) This invention aims to enable efficient and accurate inspection of filter circuits without the need to change the frequency of the inspection signal. purpose.

(Means for Solving the Problems) This invention does not use a conventional sine wave signal with a variable frequency as an inspection signal, but instead uses a square wave signal with a constant frequency. It is characterized in that the output from the filter circuit when given is compared with a predetermined reference value at a DC level.

(Example) An example of the present invention will be described with reference to FIG.
Note that parts given the same reference numerals as in FIG. 6 indicate the same or corresponding parts. According to the invention, a square wave signal of constant amplitude and constant frequency is used as the inspection signal. 21 is a square wave oscillator that outputs such a square wave signal. Here, when the target is a bandpass filter circuit whose center frequency is F ₀ as shown in Figure 3, the square wave signal has an amplitude of 1 as shown in Figure 2, and a period T where 1/F ₀ = T.
The square wave signal of is used as the inspection signal.

When we expand a square wave signal like this, we get f(t)=1/2+2/π(sinωt+1/3sin3ωt +1/5 sin5ωt…) becomes.

When the above square wave signal is input as a check signal to a panned pass filter circuit, assuming that the gain of this filter circuit is 1 and the Q is extremely large, if the filter circuit is normal at this time, the fundamental wave component will be detected. only passes through.

22 is a reference value circuit, which outputs a signal (DC voltage) of the same magnitude as the output from the conversion circuit 8 as a reference signal when the inspection signal is applied to the filter circuit 1 in a normal state. .

In the above configuration, when inspecting the filter circuit 1, the changeover switches 5 and 10 are respectively switched to the terminal 6 to which the output of the square wave oscillation circuit 21 is applied and the terminal 11 to which the output of the reference value circuit 22 is applied. If the filter circuit 1 is normal as described above, only the fundamental wave component passes through, so the output from the conversion circuit 8 will be 2/π (=approximately 0.64).

However, if the fundamental frequency of the filter circuit 1 deviates or the gain at the fundamental frequency decreases, then the output from the conversion circuit 8 will be smaller than the reference signal. Furthermore, if the gain in the low or high range is higher than a predetermined value, the component called (2/3π)sin3ωt, which is 1/2 of the DC component in the above expansion or the harmonic component, will affect it. The output from the conversion circuit 8 at this time becomes larger than 2/π.

As described above, the reference value from the reference value circuit 22 outputs a signal having a value corresponding to this output 2/π as a reference signal. Comparison circuit 13 compares whether the output from conversion circuit 8 is within a predetermined range centered on this reference value signal. When it is within this range, it is determined that the filter circuit 1 is normal, and when it is outside this range, it is determined that it is defective.
A signal to that effect is output to the terminal 14. The above allows inspection of the filter circuit 1.

In this case, since the output of the conversion circuit 8 is a DC voltage, the comparison circuit 13 can compare the output of the conversion circuit 8 and the reference output of the reference circuit 22 at the DC level.

The square wave signal shown in Fig. 2 was a waveform signal that included a DC component, but instead, as shown in Fig. 4, a waveform that does not contain a DC component, that is, the amplitude is ±
Alternatively, one square wave signal may be used. In this case, in order to be able to check the low-frequency characteristics of the filter circuit 1, it is preferable to use a filter that satisfies the relationship T>1/F ₀ for its period T, as shown in FIG.

The repetition period of the square wave at this time is a frequency period near and lower than the center frequency of the filter.

Although each circuit has been described above as being of an analog type, it is not limited to this, and it goes without saying that it may be of a digital type.
Further, the present invention is applicable whether the filter circuit is an analog type or a digital type.

(Effects of the Invention) As detailed above, according to the present invention, the filter circuit can be controlled simply by using a square wave signal of one type of frequency, instead of using sine wave signals of various frequencies as in the past. Inspection is possible, and since such a square wave signal can be easily generated compared to the sine wave signal described above, and this inspection only requires comparing DC levels,
There is no need for pattern recognition of response waveforms, and therefore a configuration for inspection can be obtained more easily than conventional configurations.

[Brief explanation of drawings]

Fig. 1 is a circuit diagram showing an embodiment of this invention, Fig. 2 is a circuit diagram showing an embodiment of the present invention;
The figure is a waveform diagram of a square wave signal, Figure 3 is a filter characteristic diagram, Figure 4 is a waveform diagram of another example of a square wave signal, and Figure 5 is a waveform diagram of a square wave signal.
This figure is a filter characteristic diagram of another example, and FIG. 6 is a circuit diagram of a conventional example. 1... Filter circuit, 8... Conversion circuit, 13...
... Comparison circuit, 21 ... Square wave oscillator, 22 ... Reference value circuit.

Claims (1)

[Claims] 1. Means for applying a square wave signal of a constant frequency having a frequency at or near the center frequency of the filter circuit to be inspected to the filter circuit as an inspection signal, when the filter circuit is in a normal state,
Reference value signal generation means for outputting a signal having a magnitude corresponding to the output of the filter circuit when the inspection signal is applied to the filter circuit as a reference value signal, and the filter circuit when the inspection signal is applied. a conversion means for converting the output from the reference value signal into a DC voltage, and a reference value signal from the reference value signal generation means and the DC voltage from the conversion means are compared, and the DC voltage is within a predetermined range including the reference value signal. A filter inspection device comprising comparison means for comparing whether or not the difference is within the range.