JPH10260209A - Pulse signal classifying device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To separate them as a different pulse signal even if a peak level and level width are same by adding inclination equivalent in a significant pulse rise waveform or fall waveform specific part and analyzing and classifying a pulse train. SOLUTION: The peak level 9 and the peak time 18 of the pulse quantization signal 4 of a pulse video signal 2 is detected by a peak detector. A pulse rise inclination calculator divides a difference ΔPA1 between the peak level 9 and a rise level 19 by a difference Δt1 between the peak time 18 and a rise time 13, and finds rise inclination 21. An intermediate rise inclination calculator divides a difference ΔPA2 between the peak level 49 and an intermediate rise level 23 nearest the intermediate level of the peak level 9 and the rise level 19 in the rise level 19 by a difference Δt2 between an intermediate rise time 24 and the rise time 13, and finds intermediate rise inclination 26. Correlation of a video pulse signal 2 is taken by the peak level 9, pulse width 17 and each inclination 21, 26, and classification is performed.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a pulse signal classifying apparatus for extracting characteristics by paying attention to a pulse waveform in addition to a peak level, a pulse width, and a pulse period of an input pulse signal, and classifying the pulse signal. is there.

[0002]

2. Description of the Related Art As a conventional pulse signal classifying apparatus of this type, an apparatus utilizing both a rising slope and a falling slope of a pulse signal in addition to a general pulse height, width and frequency is disclosed, for example, in Japanese Patent Application Laid-Open No. 7-1995. 84031. However, the purpose of the above-described device is to easily process the received signal with a small-scale device. Specifically, the received wave is first sampled, the sampling points are connected, and the time is set from the extended intersection. It is to be calculated. Therefore, there is no mention of the feature extraction of the pulse waveform.

FIG. 28 is a block diagram showing a configuration of a general conventional pulse signal classification device different from the above-described device. In the figure, reference numeral 1 denotes an A / D converter which samples a pulse video signal 2 at a constant interval and converts it into a digital signal; 3 denotes a pulse quantized signal 4 quantized by the A / D converter 1 and a predetermined threshold level 5; And a pulse specification measurement controller that outputs a pulse specification measurement instruction 6 from when the pulse quantized signal 4 becomes higher than the threshold level 5 until it becomes lower than the threshold level 5, a timer unit 7 for measuring time, 8a Is a peak level detector that detects the peak level 9 of the pulse quantized signal 4, 10 is a pulse width measurement level calculator that calculates a pulse width measurement level 11 that is lower than the peak level 9 by a predetermined level, and 12 is a pulse rising portion. The rising detector 14 detects the rising time 13 of the pulse quantized signal 4 closest to the pulse width measurement level 11 at 14. A falling detector for detecting the falling time 15 of the pulse quantized signal 4 closest to the pulse measurement level 11 in the falling portion, and a pulse 16 for calculating the pulse width 17 by taking the difference between the falling time 15 and the rising time 13 The width calculator 64a is a correlator that correlates the pulse signal based on the peak level 9 and the pulse width 17.

Next, the operation will be described. FIG. 29 is a diagram showing a timing chart of each signal in the above-described conventional pulse signal classification device. In the figure, FIG.
The same reference numerals indicate the same signal, time, and the like. The A / D converter 1 samples the input pulse video signal 2 at regular intervals and outputs a pulse quantized signal 4. The pulse specification measurement indicator 3 includes a pulse quantized signal 4 and a threshold level 5
And outputs a pulse specification measurement instruction 6 from the time when the pulse quantized signal 4 becomes higher than the threshold level 5 until it becomes lower. The peak detector 8a holds the maximum level value of the pulse quantized signal 4 while the pulse specification measurement instruction 6 is being output.
The held data is output as the peak level 9. Then
The pulse width measurement level calculator 10 calculates the pulse width measurement level 11 which is a predetermined level from the A / D output 4 in the range indicated by the pulse specification measurement instruction 6 by calculating backward from the peak level 9 and calculates the level value. Output. Rise detector 14
Holds the level and the time when the pulse quantization signal 4 increases, and detects the pulse quantization signal 4 closest to the pulse width measurement level 11 from the held data after the output of the pulse specification measurement instruction 6 is completed. And outputs rise time 13. The falling detector holds the level when the pulse quantized signal 4 decreases and the time at which the pulse quantization signal 4 has decreased.
Fall time 15 of the pulse quantization signal 4 closest to 1
Is detected and output. The pulse width calculator 16 calculates the difference between the falling time 15 and the rising time 13 and calculates the pulse width 17
Is calculated and output. Next, the correlator 64a correlates the pulse signals based on the peak level 9 and the pulse width 17, and performs classification.

[0005]

Since the conventional pulse signal classifying apparatus is configured as described above, even if different waveforms have the same peak level 9 and pulse width 17 as shown in FIG. There was a problem of being classified.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and strictly classifies different waveforms as different pulse signals even if the peak level 9 and the pulse width 17 are the same for different waveforms. It is an object to obtain a pulse signal classification device.

[0007]

SUMMARY OF THE INVENTION A pulse signal classifying apparatus according to the present invention detects a period and a height of an input pulse train at or above a predetermined level as significant pulses, and analyzes the specifications of the significant pulses. In the configuration, a specific portion rising or falling slope detector for detecting a slope corresponding to a specific portion of a rising or falling waveform of a significant pulse is provided. The input pulse train was analyzed and classified.

Still further, as a specific partial rising slope detector, a rising slope detector for detecting a predetermined level and a peak value of a rising waveform of a significant pulse, and a slope corresponding to a substantially middle point between the predetermined level and the peak value, and an intermediate rising slope detector An inclination detector was used.

Further, as a specific portion rising slope detector, when a significant pulse has a pulse flat portion having the broadest and almost flat pulse height, the slope corresponding to the point where the rising waveform reaches the pulse flat value is determined. A pulse flat level rising slope detector to be detected was used.

Still further, as the specific portion rising slope detector, a plurality of rising slope detectors for detecting the slopes at a plurality of points between a predetermined level and a peak value of a significant pulse rising waveform are provided.

Further, as the specific portion falling slope detector, a falling slope detector for detecting a slope from a peak value of a significant pulse falling waveform to a predetermined level is used.

Still further, as the specific part rising slope detector or the specific part falling detector, a rising slope detector, an intermediate rising slope detector, a pulse flat level rising slope detector, a plurality of rising slope detectors, and a falling end point. One of the tilt detectors was used in combination.

[0013]

BEST MODE FOR CARRYING OUT THE INVENTION

Embodiment 1 FIG. Here, an input pulse having a level equal to or higher than a set level is extracted as a significant pulse, and the slope of the rising waveform is considered as a feature and is used as a classification factor. A pulse signal fractionation apparatus according to Embodiment 1 of the present invention will be described with reference to the drawings. FIG. 1 is a block diagram showing a configuration of the pulse signal classification device. In the figure, the same reference numerals as those in FIG. 28 indicate the same or corresponding parts. Reference numeral 8b denotes a peak detector for detecting the peak level 9 of the input pulse quantized signal and its time, and reference numeral 20 denotes a difference between the above-mentioned peak level 9 and the rising level 19 by a difference between the peak time 18 and the rising time 13. A rising slope calculator for calculating a rising slope 21; an intermediate rising detector 22 for detecting the level of the pulse quantization signal closest to the intermediate level between the peak level 9 and the rising level 19 in the rising portion and the time; 25 is the difference between the intermediate rising level 23 and the rising level 19,
An intermediate rising slope calculator that calculates the intermediate rising slope 26 by dividing by the difference between
Is a peak level 9, a pulse width 17, and a rising slope 21.
And a correlator that correlates the pulse signal with the intermediate rising slope 26. That is, in the present embodiment, a rising slope detector and an intermediate rising slope detector are used as a specific part rising or falling detector that detects the characteristic of the waveform of the significant pulse and detects the slope of a specific part of the rising or falling waveform. ing.

Next, the operation will be described. FIG. 2 is a diagram showing a timing chart of each signal in the pulse signal classifying device according to the embodiment of the present invention. In FIG. 2, signals having the same reference numerals and times as those in FIG. Show. The A / D converter 1 samples the pulse video signal 2 at regular intervals and outputs a pulse quantized signal 4. The pulse specification measurement indicator 3 compares the pulse quantized signal 4 with the threshold level 5 and outputs a pulse specification measurement instruction 6 during a period from when the pulse quantized signal 4 becomes higher than the threshold level 5 until it becomes lower. . The peak level detector 8b holds the maximum level value of the pulse quantized signal 4 and its time while the pulse specification measurement instruction 6 is being output, and after the pulse specification measurement instruction 6, the held data is held at the peak level. 9,
Output as peak time 18. Next, the pulse width measurement level calculator 10 calculates a pulse width measurement level 11, which is a predetermined level value calculated backward from the peak level 9, and outputs the value. The rising detector holds the level and time when the pulse quantization signal 4 increases, and after the output of the pulse specification measurement instruction 6 is completed, the pulse quantization signal 4 closest to the pulse width measurement level 11 from the held data. Is detected and the rise time 13 is output. The falling detector holds the level and the time when the pulse quantization signal 4 decreases, and after the output of the pulse specification measurement instruction 6 is completed, the pulse quantization signal 4 closest to the pulse measurement level 11 from the held data. At the falling time 15 is output. The pulse width calculator 16 calculates the difference between the falling time 15 and the rising time 13 to calculate and output a pulse width 17 that is equal to or larger than the above-described predetermined level value.

The pulse rising slope calculator 20 divides the difference between the peak level 9 and the rising level 19 by the difference between the peak time 18 and the rising time 13 to calculate and output the rising slope 21. That is, ΔPA1 / Δt1 in FIG.
Is output. The intermediate rising detector 22 detects and outputs the level of the pulse quantization signal closest to the intermediate level between the peak level 9 and the rising level 19 in the rising portion, that is, 23 in FIG.
The intermediate rise slope calculator 25 divides the difference between the intermediate rise level 23 and the rise level 19 by the difference between the intermediate rise time 24 and the rise time 13 to calculate and output the intermediate rise slope 26. That is, ΔPA2 in FIG.
/ Δt2. Next, the correlator 64b correlates and classifies the pulse signals based on the peak level 9, the pulse width 17, the rising slope 21 and the intermediate rising slope 26.

FIG. 3 shows an example of a circuit configuration of the above-described peak detector 8b. In FIG. 3, the same applies to FIG. 4 and FIG. The peak detection controller 100 controls the updating of the peak level register 101 and the peak time register 102 while the pulse specification measurement instruction 6 is being output. The pulse quantized signal 4 and the peak level 9 output from the peak level register 101 are compared with the comparator 1
If the pulse quantization signal 4 is larger, the peak detection controller 100 writes the level in the peak level register 101 and the time 104 in the peak time register 102 to update the data. As described above, the peak level 9 and the peak time 18 are detected.

FIG. 4 shows an example of a circuit configuration of the rising detector 12 described above. While the pulse specification measurement instruction 6 is being output, the rise detection controller 200 performs update control of the previous pulse quantization signal register 201 and write control of the rise candidate register group 202. Pulse quantization signal 4
And the output of the previous pulse quantization signal register 201 to the comparator 2
If the pulse quantization signal 4 is large, the level and the time are written in the rising candidate register group 202. After the output of the pulse specification measurement instruction 6 is completed, the rising selector 204 selects the level closest to the pulse width measurement level 11 from the rising candidate register group 202 and outputs it as the rising level 19 and the rising time 13. As described above, the rise level 19 and the rise time 13 are detected.

FIG. 5 shows a circuit configuration example of the intermediate rising detector 22. While the pulse specification measurement instruction 6 is being output, the intermediate rise detection controller 300 performs update control of the previous pulse quantization signal register 301 and write control of the rise candidate register group 302. The pulse quantized signal 4 and the output of the previous pulse quantized signal register 301 are compared by a comparator 303, and if the pulse quantized signal 4 is large, the level and the time are written to the intermediate rising candidate register group 302. After the output of the pulse specification measurement instruction 6, the intermediate rising selector 304 selects the level closest to the middle of the difference between the peak level 9 and the pulse width measurement level 11 from the intermediate rising candidate register group 302. Output as the intermediate rise time 24. As described above, the detection of the intermediate rising level 23 and the intermediate rising time 24 is performed. Although the inclination is obtained in the above configuration, the angle may be obtained from tan ^-1 ΔPA / Δt, and the feature may be extracted by the angle. In any case,
Since the rising slope of the pulse is also used as one classification criterion, more precise pulse classification can be performed in combination with other pulse data such as the pulse width.

Embodiment 2 In the first embodiment,
The correlator classifies pulse signals by correlating peak levels, pulse widths, rising slopes, and intermediate rising slopes, but instead uses the rising slopes at arbitrary multiple points in the rising waveform. Will be described. FIG. 6 is a block diagram showing a configuration of the pulse signal classification device according to the second embodiment. As in the following description, in the figure, elements and signals having the same reference numerals as those in FIG. 1 indicate the same or corresponding parts. Reference numeral 27 denotes a pulse which outputs the level of the pulse quantized signal 4 and its time between the rising time 13 and the peak time 18 by chronologically arranging and holding the level of the pulse quantized signal 4 and the time at the pulse rising portion. The rising waveform recorder 30 includes rising pulse quantization signal levels 28-1 to n output from the pulse rising waveform recorder 27 and a rising level 19.
Is divided by the difference between the rising pulse quantized signal times 29-1 to 29-n output from the pulse rising waveform recorder and the rising time 13 to calculate a plurality of rising slopes 31-1 to 31-n in the pulse rising portion. And a plurality of rising slope calculators 64c to output a peak level 9
And a pulse width 17, a rising slope 21, and a plurality of rising slopes 31-1 to 31-n.

Next, the operation will be described. FIG. 7 is a diagram showing a timing chart of each signal in the pulse signal classification device according to the second embodiment. Even so,
In the figure, the signal and time represented by the same reference numerals as those in the previous figure are:
This is shown in the same part of the previous figure. The pulse rising waveform recorder 27 arranges and holds the level of the pulse quantized signal 4 and its time in a pulse rising portion in a time series, and holds the level of the pulse quantized signal between the rising time 13 and the peak time 18 and its level. Print the time. The plurality of rising slope calculators 30 calculate the difference between the rising pulse quantization signal levels 28-1 to n output from the pulse rising waveform recorder 27 and the rising level 19 by using the rising pulse quantization output from the pulse rising waveform recorder. The signal is divided by the difference between the signal times 29-1 to 29-n and the rising time 13 to calculate and output a plurality of rising slopes 31-1 to 31-n in the pulse rising portion. Next, the correlator 64c correlates the pulse signals based on the peak level 9, the pulse width 17, the rising slope 21, and the plurality of rising slopes 31-1 to 31-n to perform classification.

FIG. 8 shows a circuit configuration example of the pulse rising waveform recorder 27. Pulse rising waveform recording controller 4
In step 00, while the pulse specification measurement instruction 6 is being output, the control of updating the previous pulse quantization signal register 401 and the control of writing to the pulse rise register group 402 are performed. Pulse quantized signal 4 and previous pulse quantized signal register 40
One output is compared by the comparator 403, and if the pulse quantization signal 4 is small, the level and the time are written into the pulse rising register group 402. After the output of the pulse specification measurement instruction 6 is completed, the pulse rise selector 404 determines the level of the pulse quantization signal between the rise time 13 and the peak time 18 and the rise time of the pulse quantization signal level 28.
-1 to n and the rising pulse quantized signal time 29-1
To n. When the rising slope detector and a plurality of rising slope detectors are used together as the specific part rising slope detector, the circuit becomes slightly more complicated but more strict pulse classification can be performed.

Embodiment 3 FIG. In the first embodiment,
The correlator correlates pulse signals by peak level, pulse width, rising slope, and intermediate rising slope, but instead uses them to find the slope until the rising waveform becomes a stable flat surface near the wave height. A case where classification is performed using a pulse flat level rising slope will be described. FIG. 9 is a block diagram showing a configuration of the pulse signal dividing device according to the third embodiment. In the figure, 32
Is a pulse flat average level detector for detecting an average level in a section where the pulse quantized signal 4 has a flat pulse flat level, and 34 is a pulse quantized signal closest to a pulse flat average level 33 in a pulse rising portion. Rising pulse flat level detector 37 for detecting the level and the time of the rising edge.
Is divided by the difference between the pulse flat level rising time 36 and the rising time 13 to calculate a pulse flat level rising slope 38. 64d is a peak level 9, a pulse width 17, and a pulse flat level. This is a correlator that correlates the pulse signal with the rising slope 38.

Next, the operation will be described. FIG. 10 is a diagram showing a timing chart of each signal in the pulse signal classification device according to the third embodiment. The pulse flat average level detector 32 detects an average level in a section where the pulse quantized signal 4 has a predetermined flat pulse flat level. After the output of the pulse specification measurement instruction 6 is completed, the rising pulse flat level detector 34 detects the level of the pulse quantization signal closest to the pulse flat average level 33 in the pulse rising portion and the time. Pulse flat level rising slope calculator 37
Calculates the pulse flat level rising slope 38 by dividing the difference between the rising pulse flat level 35 and the rising level 19 by the difference between the pulse flat level rising time 36 and the rising time 13. Next, the correlator 64d correlates the pulse signals based on the peak level 9, the pulse width 17, and the pulse flat level rising slope 38, and performs classification.

FIG. 11 shows a circuit configuration example of the pulse flat average level detector 32. The pulse flat average level detection controller 500 controls the update of the previous pulse quantization signal register 501, the count control of the pulse flat time counter 502, and the pulse flat level adder 503 while the pulse specification measurement instruction 6 is being output. Performs addition control. The absolute value of the difference between the pulse quantized signal 4 and the output of the previous pulse quantized signal register 501 is obtained by the subtractor 504. Next, the output of the subtractor 504 and the pulse flat level range 50
The comparison of No. 5 is performed by the comparator 506. If the output of the subtractor 504 is smaller than the pulse flat level range 505, the pulse flat time counter 502 starts counting,
The output of the previous pulse quantization signal register 501 is added to the pulse flat level adder 503. After the count starts, the output of the subtractor 503 is changed to the pulse flat level range 50.
If it becomes larger than 5, the counting and the addition are stopped. Next, after the output of the pulse specification measurement instruction 6 is completed, the pulse flat average level calculator 507 outputs the output of the pulse flat level adder 503 to the pulse flat time counter 502.
Divide by the output to calculate and output the pulse flat average level 33. As described above, the detection of the pulse flat average level 33 is performed.

FIG. 12 shows an example of a circuit configuration of the rising pulse flat level detector 34. The rising pulse flat level detection controller 600 outputs a pulse specification measurement instruction 6
Is output, the previous pulse quantization signal register 6
01 and write control of the rising pulse flat level candidate register group 602 are performed. The pulse quantized signal 4 is compared with the output of the previous pulse quantized signal register 601 by the comparator 603. If the pulse quantized signal 4 is large, the level and the time are written into the rising pulse flat level candidate register group 602. After the output of the pulse specification measurement instruction 6, the rising pulse flat level selector 604 selects the level closest to the pulse flat average level 33 from the rising pulse flat level candidate register group 602, and sets the rising pulse flat level 35 and the pulse flat level. Output as rising time 36. As described above, the rising pulse flat level 35 and the pulse flat level rising time 36 are detected.

There are many possible changes in the present embodiment.
For example, a case will be described in which a pulse flat middle rising slope until reaching a half value of the pulse flat level is used in addition to the configuration of FIG. FIG. 13 is a block diagram showing a configuration of a pulse signal classification device using both a pulse flat level rising slope detector and a pulse flat middle rising slope detector. In the figure, reference numeral 39 denotes a pulse flat intermediate level rising detector which detects the level of the pulse quantized signal closest to the intermediate level between the pulse flat average level and the rising level 19 in the rising portion and the time thereof; And a rising level 19 are divided by the difference between the pulse flat level intermediate level rising time 41 and the rising time 13 to calculate a pulse flat intermediate level rising slope 43. A pulse flat intermediate level rising slope calculator 64e is a correlator. is there.

Since the operation of the apparatus having this configuration can be easily estimated from the apparatus of the above embodiment, a detailed description is omitted. As a precautionary measure, a timing chart showing each signal in the present pulse signal classification device is shown in FIG. FIG. 15 is a diagram showing a circuit of the pulse flat intermediate level rising detector 39. In FIG. 15, the pulse flat intermediate level rising detection controller 700 controls the updating of the previous pulse quantization signal register 701 and writes the pulse flat intermediate level rising candidate register group 702 while the pulse specification measurement instruction 6 is output. Perform control. The comparator 703 compares the pulse quantization signal 4 with the output of the previous pulse quantization signal register 701. If the pulse quantization signal 4 is large,
The level and the time are written in the pulse flat intermediate level rising candidate register group 702. After the output of the pulse specification measurement instruction 6, the pulse flat intermediate level rising selector 704 selects the level closest to the middle between the pulse flat average level 33 and the rising level 19 from the pulse flat intermediate level rising candidate register group 702, and It is output as a flat middle rising level 40 and a pulse flat level middle level rising time 41.

FIG. 16 is also a block diagram showing a configuration of a pulse signal classifying apparatus using both a pulse flat rising slope detector and a plurality of rising slope detectors. In the figure, reference numeral 44 denotes the level of the pulse quantized signal and the time of the pulse quantized signal in the pulse rising portion, which are arranged in time series and held.
Rise level 19 to pulse flat average level 3
A pulse rising waveform recorder for outputting the level of the pulse quantized signal between 3 and its time, and 47 is a difference between the rising pulse quantized signal levels 45-1 to 45-n output from the pulse rising waveform recorder 44 and the rising level 19. Is divided by the difference between the rising pulse quantized signal times 46-1 to 46-n output from the pulse rising waveform recorder and the rising time 13, to calculate and output a plurality of rising slopes 48-1 to 48-n in the pulse rising portion. A plurality of rising slope calculators 64f are correlators for correlating pulse signals. The operation of this device is also evident from the description of the operation of the same components as described above, and thus detailed description is omitted. As a precautionary measure, a timing chart showing each signal in the present pulse signal classification device is shown in FIG.

FIG. 18 shows a pulse rise waveform recorder 44.
FIG. 3 is a diagram showing a circuit configuration example of FIG. In FIG. 18, while the pulse specification measurement instruction 6 is being output, the pulse rise waveform recording controller 800 controls updating of the previous pulse quantization signal register 801 and the pulse rise register group 80.
2 is controlled. The pulse quantized signal 4 is compared with the output of the previous pulse quantized signal register 801 by the comparator 803. If the pulse quantized signal 4 is smaller, the level and the time are written in the pulse rise register group 802.
After the output of the pulse specification measurement instruction 6 is completed, the pulse rising selector 804 determines the level of the pulse quantization signal between the rising level 19 and the pulse flat average level 33 and the time thereof, and the rising pulse quantization signal levels 45-1 to n.
And rising pulse quantized signal times 46-1 to 46-n.

Embodiment 4 The characteristics of the input pulse may be interpreted as a difference in falling slope instead of various rising slopes. Hereinafter, a typical case will be described. FIG. 19 is a block diagram showing a configuration of a pulse signal classification device according to Embodiment 4 of the present invention. In this configuration, a feature is extracted as a falling slope from the peak level until the level decreases to a predetermined value. In the figure, reference numeral 49 denotes a falling start level 5 lower than the peak level 9 by a predetermined level.
A falling start point calculator 51 for calculating 0, a falling start point detector 51 for detecting the level of the pulse quantized signal closest to the falling start level 50 of the pulse falling portion and the time thereof, and a peak level 9 for the peak level 9 A fall start point slope calculator that divides the difference between the fall start point level 52 by the difference between the fall start point time 53 and the peak time 18 to calculate a fall start point slope 55, and a correlator 64g that correlates with these signals. It is.

Next, the operation will be described. FIG. 20 is a diagram showing a timing chart of each signal in the above-described pulse signal classification device. Fall start point level calculator 49
Calculates the falling start level 50 lower than the peak level 9 by a predetermined level. The falling start point detector 51 detects the level of the pulse quantized signal closest to the falling start point level 50 of the pulse falling portion and the time. The fall start point slope calculator 54 divides the difference between the peak level 9 and the fall start point level 52 by the difference between the fall start point time 53 and the peak time 18 to calculate a fall start point slope 55. The correlator 64g correlates the pulse signals based on the peak level 9, the pulse width 17, and the falling starting point slope 55, and performs classification.

FIG. 21 shows an example of the circuit configuration of the falling start point detector. The fall start point detection control 900 performs update control of the previous pulse quantization signal register 901 and write control of the fall start point candidate register group 902 while the pulse specification measurement instruction 6 is output. The pulse quantized signal 4 is compared with the output of the previous pulse quantized signal register 901 by the comparator 903. If the pulse quantized signal 4 is small, the level and time are written to the falling start point candidate register group 902. After the output of the pulse specification measurement instruction 6 is completed, the falling start point selector 904 sets the level closest to the falling start point measurement level 50 to the falling start point candidate register group 902.
And outputs it as the falling start point level 52 and the falling start point time 53. Thus, the falling start point level 52 and the falling start point time 53 are detected.

Various variations can be obtained depending on what is extracted as the falling slope. FIG. 22 shows another pulse signal classification device according to the present embodiment. In the figure, 57 is a falling end slope calculator for dividing the difference between the peak level 9 and the falling level 56 by the difference between the falling time 15 and the peak time 18 to calculate the falling end slope 58, and 64h is based on these signals. This is a correlator for correlating pulse signals. FIG. 23 is a timing chart illustrating the operation of the above-described device. The falling end slope calculator 57 calculates the peak level 9 and the falling level 56.
Is divided by the difference between the fall time 15 and the peak time 18 to calculate the fall end slope 58. Correlator 64
h is classified by taking correlation of pulse signals.

FIG. 24 shows an example of the circuit configuration of the falling detector 14. While the pulse introduction measurement instruction 6 is being output, the fall detection controller 1000 performs update control of the previous pulse quantization signal register 1001 and write control of the fall candidate register group 1002. The pulse quantized signal 4 is compared with the output of the previous pulse quantized signal register 1001 by the comparator 1003. If the pulse quantized signal 4 is small, the level and the time are set to the falling candidate register group 10
Write to 02. After the pulse specification measurement instruction 6 has been output,
The falling selector 1004 selects the level closest to the pulse width measurement level 11 from the falling candidate register group 1002, and selects the falling level 56 and the falling time 15.
Output as

FIG. 25 shows still another pulse signal classification device according to the present embodiment. In the figure, reference numeral 59 denotes a pulse flat falling level detector for detecting the level of the pulse quantized signal closest to the pulse flat average level in the falling portion and its time, and 62 denotes a peak level 9
The pulse flat falling slope calculator for detecting the pulse flat falling slope 63 by dividing the difference between the pulse flat falling level 60 and the pulse flat falling time 61 by the difference between the pulse flat falling time 61 and the peak time 18. Is a correlator that takes the correlation of FIG. 26 is a timing chart illustrating the operation of the above-described device. The pulse flat falling level detector 59 detects the level of the pulse quantization signal closest to the pulse flat average level in the falling portion and the time. The pulse flat falling slope calculator 62 divides the difference between the peak level 9 and the pulse flat falling level 60 by the difference between the pulse flat falling time 61 and the peak time 18 to calculate and output the pulse flat falling slope 63. I do. The correlator 64i correlates the pulse signals to perform classification.

FIG. 27 shows a circuit configuration example of the falling pulse flat level detector 59. The falling pulse flat level detection controller 1100 controls updating of the previous pulse quantization signal register 1101 and writing control of the falling pulse flat level candidate register group 1102 while the pulse specification measurement instruction 6 is being output. Pulse quantized signal 4 and previous pulse quantized signal register 1101
The outputs are compared by a comparator 1103, and if the pulse quantized signal 4 is smaller, the level and the time are written to the falling pulse flat level candidate register group 1102. After the output of the pulse specification measurement instruction 6 is completed, the falling pulse flat level selector 1104 outputs the pulse flat average level 3
The level closest to 3 is selected from the falling pulse flat level candidate register group 1102, and is output as a falling pulse flat level 60 and a pulse flat level falling time 61.

It is to be noted that the pulse signal classification devices in the above embodiments may be used in combination. That is, various rising inclination detectors or falling inclination detectors are used together. By doing so, more strict pulse waveform analysis can be performed, and fine classification can be performed.

[0038]

As described above, according to the present invention, in addition to the peak level, the pulse width, and the pulse period, a specific portion rising slope detector or falling slope detector is provided to perform pulse classification. This has the effect of preventing erroneous classification of similar pulses due to the peak level and pulse width of the pulse, and enabling strict pulse classification.

[Brief description of the drawings]

FIG. 1 is a block diagram illustrating a configuration of a pulse signal classification device according to Embodiment 1 of the present invention.

FIG. 2 is a diagram showing a timing chart of each signal in the first embodiment.

FIG. 3 is a circuit configuration diagram of a peak detector according to the first embodiment.

FIG. 4 is a circuit configuration diagram of a rising detector according to the first embodiment;

FIG. 5 is a circuit configuration diagram of an intermediate rising detector according to the first embodiment;

FIG. 6 is a block diagram showing a configuration of a pulse signal classification device according to a second embodiment of the present invention.

FIG. 7 is a diagram showing a timing chart of each signal in the second embodiment.

FIG. 8 is a circuit configuration diagram of a pulse rising waveform recorder according to the second embodiment.

FIG. 9 is a block diagram showing a configuration of a pulse signal classification device according to Embodiment 3 of the present invention.

FIG. 10 is a diagram showing a timing chart of each signal in the third embodiment.

FIG. 11 is a circuit configuration diagram of a pulse flat average level detector according to the third embodiment.

FIG. 12 is a circuit configuration diagram of a rising pulse flat level detector according to the third embodiment.

FIG. 13 is a block diagram showing a configuration of another pulse signal classification device according to the third embodiment.

14 is a diagram showing a timing chart of each signal in the device of FIG.

FIG. 15 is a circuit configuration diagram of a pulse flat intermediate level rising detector in the device of FIG. 13;

FIG. 16 is a block diagram showing a configuration of still another pulse signal classification device according to the third embodiment.

17 is a diagram showing a timing chart of each signal in the device of FIG. 16;

18 is a circuit configuration diagram of a pulse rising waveform recorder in the apparatus of FIG.

FIG. 19 is a block diagram showing a configuration of a pulse signal classification device according to a fourth embodiment of the present invention.

FIG. 20 is a diagram showing a timing chart of each signal in the fourth embodiment.

FIG. 21 is a circuit configuration diagram of a falling start point detector according to the fourth embodiment.

FIG. 22 is a block diagram showing a configuration of another pulse signal classification device according to the fourth embodiment.

23 is a diagram showing a timing chart of each signal in the device of FIG.

24 is a circuit configuration diagram of a falling detector in the device of FIG.

FIG. 25 is a block diagram showing a configuration of still another pulse signal classification device according to the fourth embodiment.

26 is a diagram showing a timing chart of each signal in the device of FIG. 25.

FIG. 27 is a circuit configuration diagram of a falling pulse flat level detector in the device of FIG. 25.

FIG. 28 is a block diagram showing a configuration of a conventional pulse signal classification device.

FIG. 29 is a diagram showing a timing chart of each signal in the conventional pulse signal classification device.

FIG. 30 is a diagram illustrating erroneous detection of a pulse waveform in a conventional pulse signal classification device.

[Explanation of symbols]

1 A / D converter, 2 pulse video signal, 3 pulse specification measurement controller, 4 pulse quantization signal, 5 threshold level, 6 pulse specification measurement instruction, 7 timer device, 8
Peak detector, 9 peak level, 10 pulse width measurement level calculator, 11 pulse width measurement level, 12 rising detector, 13 rising time, 14 falling detector, 15 falling time, 16 pulse width calculator, 17 pulses Width, 18 peak time, 19 rising level, 20 rising slope calculator, 21 rising slope, 22 intermediate rising detector, 23 intermediate rising level, 24 intermediate rising time, 25
Intermediate rising slope calculator, 26 Intermediate rising slope, 27 pulse rising waveform recorder, 28 rising pulse quantized signal level, 29 rising pulse quantized signal time, 30 multiple rising slope calculator, 3
1 Multiple rising slopes, 32 pulse flat average level detector, 33 pulse flat average level, 34
Rising pulse flat level detector, 35 rising pulse flat level, 36 pulse flat level rising time, 37 pulse flat level rising slope calculator, 38 pulse flat level rising slope, 39 pulse flat middle level rising detector, 40 pulse flat middle rising detector Level 4,
1 pulse flat level intermediate level rise time,
42 pulse flat middle level rising slope calculator, 43 pulse flat middle level rising slope,
44 pulse rising waveform recorder, 45 rising pulse quantization signal level, 46 rising pulse quantization signal time, 47 multiple rising slope calculator, 48
A plurality of rising slopes, 49 falling starting point level calculator, 50 falling starting point level, 51 falling starting point detector, 52 falling starting point level, 53 falling starting point time, 54 falling starting point slope calculator, 55
Fall start slope, 56 Fall level, 57
Fall end slope calculator, 58 Fall end slope, 59 Pulse flat fall level detector, 6
0 pulse flat fall level, 61 pulse flat fall time, 62 pulse flat fall slope calculator, 63 pulse flat fall slope, 64b, 64c, 64d, 64e, 64f, 64
g, 64h, 64i Correlator, 100 peak detection controller, 101 peak level register, 102 peak time register, 103 comparator, 104 time, 200
Rise detection controller, 201 Previous pulse quantization signal register, 202 Rise candidate register group, 203
Comparator, 204 rising selector, 300 middle rising detection controller, 301 previous pulse quantization signal register, 302 middle rising candidate register group, 30
3 comparator, 304 middle rising selector, 400 pulse rising waveform recording controller, 401 previous pulse quantization signal register, 402 pulse rising register group, 403 comparator, 404 pulse rising selector, 500 pulse flat average level detection controller , 5
01 previous pulse quantization signal register, 502 pulse flat time counter, 503 pulse flat level adder, 504 subtractor, 505 pulse flat level range, 506 comparator, 507 pulse flat average level calculator, 600 rising pulse flat level detection control Unit 6, 601 previous pulse quantization signal register, 602 rising pulse flat level candidate register group, 603 comparator, 604 rising pulse flat level selector, 700 pulse flat middle level rising detection controller, 701 previous pulse quantization signal register, 702 pulse flat middle level rising candidate register group, 703 comparator, 704 pulse flat middle level rising selector, 800 pulse rising waveform recording controller, 801 last pulse Quantized signal register, 802 pulse rise register group, 8
03 comparator, 804 pulse rising selector, 90
0 falling start point detection controller, 901 previous pulse quantization signal register, 902 falling start point candidate register group, 903 comparator, 904 falling start point selector, 1
000 falling detection controller, 1001 previous pulse quantization signal register, 1002 falling candidate register group, 1003 comparator, 1004 falling selector, 1100 falling pulse flat level detection controller, 1101 previous pulse quantization signal register, 110
2 falling pulse flat level candidate register group,
1103 Comparator, 1104 Falling pulse flat level selector.

Claims (6)

[Claims] 1. A configuration in which a period and a height of an input pulse train that are equal to or higher than a predetermined level are detected as a significant pulse, and specifications of the significant pulse are analyzed, wherein a rising waveform or a falling waveform of the significant pulse is provided. A specific portion rising or falling slope detector for detecting the equivalent of a slope at a specific portion, and analyzing and classifying the input pulse train in addition to the specific portion rising or falling slope detector output. Pulse signal classification device. 2. A specific part rising inclination detector,
2. A rising slope detector and an intermediate rising slope detector for detecting a predetermined level and a peak value of a significant pulse rising waveform and a slope substantially at an intermediate point between the predetermined level and the peak value. The pulse signal classification device according to the above. 3. A specific part rising inclination detector,
When a significant pulse has a pulse flat portion indicating the broadest and almost flat pulse height, a pulse flat level rising slope detector that detects a slope equivalent to a point at which the rising waveform reaches the above-mentioned pulse flat value is used. The pulse signal classification device according to claim 1, wherein: 4. A specific part rising inclination detector,
The pulse signal classification according to any one of claims 1 to 3, wherein a plurality of rising slope detectors detect slopes at a plurality of points between a predetermined level and a peak value of a rising waveform of a significant pulse. apparatus. 5. A specific part falling slope detector,
2. The pulse signal classifying device according to claim 1, wherein a falling slope detector detects a slope from a peak value of a significant pulse falling waveform to a predetermined level. 6. A rising edge detector, an intermediate rising edge detector, a pulse flat level rising edge detector, a plurality of rising edge detectors, and a falling end point gradient as the specific portion rising edge detector or the specific portion falling edge detector. The pulse signal classification device according to any one of claims 2 to 5, wherein any one of the detectors is used in combination.