DE1623657B1 - Method and circuit arrangement for the height analysis of electrical impulses - Google Patents

Description

3 4

The invention relates to a method for amplitude analysis lying in the middle of the signal pulse of electrical impulses that are close to the detection range that is equal to theirs Rising and / or falling edge glitch has moderate field. Accordingly, the following results are obtained in particular electrical impulses would give the amplitude value in the middle of time a particle counter based on the Coulter principle. 5 of each impulse can be found.

From the British patent specification 964 418 a device is known from the USA patent specification 2 996 624, which is known according to a device which allows it to operate from an impulse principle, which Wallace H. Coulter with any Pulse shape with the greatest amplitude was discovered, and this is to be determined today as the Coulter prin- ce value of the pulse, whereby the zip is already known. According to this principle, ίο the application of threshold levels, a delay that a sample amount of a suspension of a measuring limb and the removal of a short-term medium, the particles of which are to be studied, is practiced by sampling from each impulse. One of which is a narrowed path. The existing circuit, however, is unsuitable for the analysis of the presence or absence of a particle in the pulses that have glitches because the narrowed path allows a noticeable change in the effect of these glitches on the measurement of the electrical characteristics of the path. result would be increased.
This path is constructed in such a way that it is an area where the object is moderate or homogeneous. At least in the case, based on the disadvantageous influence of glitches in which the suspending medium is a conductive 20 in the pulse analysis or is at least liquid, the change mentioned is to be reduced very much. According to the invention, this is achieved approximately proportionally to the volume of the particle by every pulse to be analyzed that has caused it. integrated so that the voltage of the

In the usual industrial embodiment of the generating impulse and the associated integrated Im-Coulter principle, the narrowed field is compared with one another by a pulse voltage and, with a fine opening in a thin plate of insulating material, an abrial is formed which the impulse value and integral value are equal to The suspension to be examined is divided into two parts, each with a test of the pulse to be analyzed or the electrical detector with the aid of a sensing element integrated pulse at this point in time, which is connected to the ampli. A 30 approaching the temporal center of the pulse is marked on these electrodes and an entelectric voltage is applied. The information to be examined and the measurement information of the amplitude particle are taken at high speed through the value and passed on,
driven the opening. The impedance changes, in this way results in the analysis of the impulses generated by the passage of each particle, a higher accuracy, because the influence, are detected by some form of a 35 of the interference spikes leading to errors, especially to an electrical detector that is connected to the electrode is connected to the beginning and the end of the pulse switched off. can. With a particle counter according to the Coul-

The retroactive effect of the passage of the particles on the principle results specifically in the advantage that the the measuring circuit gives rise to electrical signals, the size of the particles, which prowenn the pulse height they are counted, an exact indication of which 40 is proportional, can be determined more precisely. this Number of particles, and through the use in this context it is mainly related to one Kind of amplitude differentiation back that the middle part of the pulse at the encoder the particles are according to their size numerator corresponds to the state in which classified by the different amplitudes of the particles being roughly in the middle of the passage pulses be classified. 45 opening are located, with further outside, i.e. temporally

When examining the particles, of which before or after occurring non-linearities

is known that they are largely off a narrow dynamic range.

of particle sizes, it has been found that a circuit arrangement for performing the

the measured particle size was higher than it would have.

meant to be. The investigation to determine the 50 is characterized according to the fact that an inte-

The reason for the apparent inaccuracy consisted of the grator intended to be analyzed

two aspects. In one of them a large number of impulses were applied so that everyone could be analyzed.

made of photographs of individual impulses, rendering impulse and its integrated impulse of a

which appeared on a cathode ray oscilloscope are fed in the same stage that a first switch

whereby these pulses result from the determination of the 55 which, with the same amplitude value of the

Single particles passing through a typical pulse to be analyzed and the integrated im-

see opening revealed. And in the other case, pulses was the corresponding part of the directly supplied

a study of the geometry of a typical particle to be analyzed or the integrated momentum

path in relation to the isopotential areas of impulse switches through for a short time. It shows

made in an opening and its immediate 60 Fig. 1 is a schematic view showing the profile

bar environment are available. The isopotential of an opening shows through the three particles along

Areas give a picture of the current density distribution. different paths A, B and C run, where

It was found that the amplitude in the resulting electrical pulses generated by

The center of an impulse is its most precise part because the corresponding particle is generated in the

Glitch peaks are shown at the beginning and at the end of pulses 55 view below the opening profile,

may be present, which by certain appear- F i g. 2 a block diagram of a device for loading

voltages, which will be described later, cause the amplitude value in the middle of a

are gentle. For most purposes, the temporal impulse according to the invention,

5 6

F i g. 3 a series of voltage curves showing where the isopotential lines 18 are closest Show signals on the same time axis that are in and parallel to each other. The graphic miscellaneous Parts of Fig. 2 occur, position of the resulting electrical pulse,

Fig. 4 is an enlarged view showing various as recorded by any device

Superimposed waveforms of pulses 5 can be shown at A in FIG. Its maximum

shows, which were generated by particles, and their int-amplitude is in the temporal momentum center

grale, and is called AMP. A denotes. The duration of the

Fig. 5 is a block diagram similar to Fig. 2, pulses is equal to the time during which the particle

wherein another embodiment of the invention is in the area of the electrical influence of the public

is shown, and was located. This area is considerably larger

Fig. 6 is an enlarged view of the tension as the length L of the opening 12, since a convex

run, some of which shown in Fig. 3 bulge of relatively high electrical

are, but modified by the device according to current density (isopotential lines 20 and 22) outside

Fig. 5. The geometrical boundaries of the opening present

It has been shown that the impulse given by a 15 is.

Particle analyzer of the type mentioned is generated when the detector, which is in no way identical in shape to the amplitude of the pulse generated by the particle under consideration, even if the particles they generate respond identically, are classifying devices according to their size. If you are a relatively large pro, they speak on the value AMP. centage, about 15 ° / o, has to small peaks customarily 20 A. This amplitude is proportional to the size of its leading edges and, occasionally, of the particle that created it. If all part also at their trailing edges. In Fig. 1 follow the paths similar to path A , top of the view showing the sectional profile of a thin or fairly close to the center of the opening 12 plate 10 in a "Coulter Counter" counting and would have all the resulting pulses to the end -Size-determining device shown to see the opening 25 of the pulse A and have only been shown in FIG. The structure is shown idealized, ie amplitudes differ from one another according to their size with a perfectly cylindrical bore and exactly. It should be noted that the sharpening edges 14 and 16. If the opening current measurements in the figures are exaggerated to turn one in the device, it flows from a better understanding of the theory of the description side to the other through the opening, such as - 30 to allow. The total duration of the pulse is wise from the left to the right. The total volume, usually on the order of 20 to 40, becomes microseconds with which the particles are de- signed. The required forming and holding electrolyte is filled, but no classification devices are used accordingly from symbols to represent it to increase the view.

to keep it as simple as possible. With flowing 35 not all particles pass through the opening 12

Electric current through the liquid is elec- tric along paths that are similar to path A. Some

current density at the opening other than those approaching along paths that are considerably out-

Current density in other parts of the liquid half of the central axis of the flowing medium

volume through which the stream flows and are on inclined or curved paths

runs. In the opening itself, the electrical 40 fluctuates, such as being drawn into the opening

Current density from place to place. The current density is shown by path C , or even closer to

at the edges 14 and 16 much larger than the corner past, as with the path B. For the pro

somewhere else. grams A to C , the same particle size was

In order to best represent this, isopotential equations are used.

lines shown in Fig. 1. These lines are close to 45 A particle on the path B provides a first thin plate perpendicular to its outer upper pulse rise, which is the part of the surface, extend across the bore 12 at 18 Chen A is very similar. However, as soon as it reaches the area in which it is almost straight, bulges at the ends 20, edge 14 forms at the associated edge and, in the case of the bulge 22, a strong impulse is a point 24. Bent in the area of the opening 12. The plate usually consists of a 50 occurs because of the even distribution of isopo-sapphire and is always made of insulating material. It is tentiallinien an almost horizontal course 28 to indicate that the electrical current density at a pulse, the size of which is approximately equal to AMP. A is. Any point proportional to the number of equi. Due to the high density of the isopotential lines in the potential surfaces in any given area of the edge 16, a further point 26 will be lumen at this point. Although the current density 55 testifies. The maximum amplitude of a particle which is generally larger than slightly traversing path B in opening 12 is with AMP. B denotes, outside the opening, is the current density at the A particle that passes through the path C, erEcken 14 and 16 where the electrical current in the outputs a pulse, which occurs 14 opening 12 in the region of the edge, at a maximum. a peak 30 with the maximum amplitude AMP. C Let there be three particle paths A, B, C through 60, in the region of the opening 12 approximately, as indicated at 32 the opening from left to right along the line, the amplitude AMP. A has taken into account at 34 dashed lines, which in Fig. 1 is just below this value,
are shown. The first particle A runs roughly According to the above explanations, the flow hangs through the center of the opening with the flow of an impulse which occurs through the influence of the increased current- runs, primarily on the size of the particle density, the maximum effect on the electrical from, but in the second place from. the area through which the resistor passes near the center of the OP particles. When all the particles pass through the

7 8

The central axis of the opening would be designated as ti, ti, t2> and tS . The time center does not pose any problems, but as shown, one of the pulse passes is at point i3.
A significant percentage of the particles near the particles. Pulse 52 becomes one through line 50

called edges. Thus, many pulses have been delivered as a result of thresholding circuit 56. This circle has a threshold level of passing through areas near the edge of higher 5, which is slightly above the noise current density disturbing peaks, which is a wrong class, so that a random noise does not produce any output qualification of the particles generating the pulses. For the sake of simplicity, this is no cause. veau in the graphic representation 42 with 58 loaded

It was pointed out that the amplitudes are plotted to represent the position of the times ti and t4 in the middle of all the impulses which are made up of parts of the io. Any signal that does not have an amplitude of the same magnitude generated, essentially which is greater than level 58, is not of the same magnitude. the threshold circuit out.

One method of generating pulses without the thresholding circuit 56 is with its output

disturbing spikes could be the account- coupled to lines 60 and 62. Rounding off the opening of the opening so that the current density 15 output signal has the shape of a square pulse 64 in the effective area of the opening practically everywhere with a low amplitude of a duration t 1 to 1 4, which is uniform. Such openings are difficult, however, as these are the corresponding times between which to be established and would very easily cross the threshold level 58 with an external pulse 52. The bodies block which, because of a wedge effect, bistable device 66 speaks to the leading edge, are not easy to remove. Another method of driving the signal 64 via a leading edge terminal could consist in passing a long opening to gate 140 and a line 141 and using and passing the resulting pulse via an electronic switch 68 via a low-pass filter, around the sharp points away connection line 70. That part of the pulse 52, to sieve. But a long opening would be expensive and that exceeds the threshold voltage 58 will be difficult to produce, the simultaneous occupation of the 25 is conducted via a line 72 to an integrator 74, opening through more than one particle would occur more frequently , Blockages would be more difficult to detect. Appearance of an ogival arch tip has, as with 76 sided, the measuring speed for a given in the graph 78 of FIG. 3 darge-pressure difference would be smaller, and the lengthened one. The curved wave begins at ti and runs for time, during which the pressurized elec- tron continues past * 3. If the integrator is in the opening through the trolyte, the total duration of the pulse 52 would be integrated, would lead to a rise in the electrolyte temperature, the heat would have to see the signal from the integrator 74 approximately and follow the deterioration of the signal-to-noise broken line that would produce conditions at the end of the curve. Another way could be shown is; but as shown, the integrator will be new to physically attempting to set the suspension in 35 before the pulse 52 has directed its development to the center of the opening, but this is complete. The integrator output also appears to be an impractical route since other lines 76 in Fig. 2 will then arise and scalefact problems will arise. gate setting circuit 78 supplied from which the

F i g. 2 illustrates in a block diagram a device which generates the resulting signal through a line 80 to the input at its output signals which are fed to the mit- 4 ° of a differential amplifier 82,
central point of the impulses of particles responding, the same period of time the impulse 52 is about the

pass through an opening. Fig. 3 shows a slide line 46 fed to the differential amplifier 82, grams of in the various parts of the scarf- The purpose of the scale factor setting circuit 78 is to according to Fig. 2 occurring pulse shapes, all of which allow the integrator 74 to run as a time-out the same timeline. 45 scale device is used. The scale factor

In the device according to Fi g. 2, the first component 40 of the circuit 78 is chosen so that the integrator has a pulse generating device, primarily an output voltage equal to that of the particle counting and sizing device after a particle pulse at the time the coulter occurs -Principle. There is an orifice tube in front of the particles getting stuck in the center of the orifice 12 that finds a tiny opening in a side 50. The differential amplifier receives both wall and this tube is filled with liquid signals and generates a signal, when the integral and immersed in a suspension to be measured, so voltage which appears on line 80 and that the opening is below the surface . the pulse signal 52 appearing on line 46, electrodes in the orifice tube and the container have the same amplitudes. The points where the two electrical signals cross each other for the sample suspension are in FIG. 3 under current through the opening. Point 80, 46 is shown on the electrodes. In detail this is in association amplifiers. The medium is explained by the opening connection with Fig.4, which presses the integrated, so that the typical impulses mentioned, which shows and normal voltage curves, as they are caused by the passage of the particles, are generated in each case similar to the particles to be begotten once. The signal which is present at the output 42 of the 60 through the opening along the path A and once a pulse generator will run various parts of the path B (Fig. 1).
Device with the help of lines 44, 46, 48 and 50 Ia Fig. 4, four curves are shown. It deals

forwarded. In FIG. 3, pos. 42, this signal is shifted around curves A and B of FIG Responding to a particle, 65 for the sake of simplicity and with regard to the fact that it runs normally through the opening, that is, without corresponding integral curves, is omitted. According to disturbing anterior or posterior peaks, the times of Fig. 3 has the normal pulse, which is divided by a part of different parts of the pulse as shown in Fig. 3. 4 chen is generated by the center of the

9 10

Opening 12 runs along path A in Fig. 1 through. Therefore, its output signal at 106 consists of the curve 52 with a peak 54 corresponding to the amplitude of the curve shown in the graph under AMP. A corresponds to. This peak occurs at time point 92 shown, but only between time t2> . If this function is integrated, ti and i4 score points. This signal is sent to a sensing element and the integrator is set so that the integral circuit 108 is fed, which outputs an output signal to the voltage value of the amplitude AMP. A on the line 110 is only generated when the specified peak, ie reached at time t3 , the output voltage is equal to zero. So-called NOR-then corresponds to the resulting function of the switch-offs work in a similar way and drawn ogival-shaped curve76. The impulse, the wise. Since at time ti a difference is caused between a particle passing through the io see the integral voltage 90 and the pulse 52 aperture along the path B , is present in FIG. 4, no output appears at 110, shown in dashed lines and denoted by 84 until there is no longer any difference. At and has a peak 24 at the amplitude AMP. B, point in time 13, when there is no longer any difference which is significantly greater than the amplitude AMP. A. That is, a small trigger signal 112 is generated. If the integration and the setting take place in this way, 15 As already stated, the time 13 is the same as described above, then the integral point corresponds to the pulse 52. This small trigger signal curves the dash-dotted curve 86. Although the integrator 112 uses a multivibrator 114 in action and the integral curve 86 intersects the pulse 84 a little earlier than the effect that it generates a short rectangular pulse 116 the integral curve 76 the pulse 52, the small one at its output 118. This pulse is a time error with practically no change in the measured value of short duration and of the order of magnitude of the instantaneous value of the voltage. Although the one or two microseconds. It is nevertheless considerably higher from peak 24 than peak 54, sufficient duration for the classification circuit to shift this additional area not to actuate the integral 86.

so far to the left that the measurement is impaired.

will. It should be noted that the signals are fed to electronic precision switches 120,

pulses 52 and 84 at time 1 1 and their decision by the line 44 to the particle pulse 52

speaking integrals begin at time ti. at the same time. Accordingly, the switch allows

The various integral curves are calculated using only a narrow section of the pulse 52, for

use of identical scale factors generated. The time output 122 to expire. This narrow section

scale is the same in all cases. The 3 ° difference results in a narrow pulse 124 of one

in the slope between the integral curves 86 and duration, which is equal to the duration of the output pulse

76 is on the difference in the course of the pulses 84 of the multivibrator 116 and is of an amplitude,

and 52 attributed. In the F i g. 3 and 4 is equal to the amplitude of the pulse 52 in its

the ordinate is not indicated in terms of value, namely the amplitude AMP. A.

because all impulses regardless of their size 35 Every impulse that emerges at output 112 has

generally have the same proportions. a duration equal to the duration of pulse 116

If with the block diagram according to FIG. 2 and is. This can, if desired, be set, the associated pulse shapes are continued, but the duration for any test run as shown in FIG. 3 then remains the same. The amplitude of each pulse, the fourth waveform below at point 80, 46 exiting the 40 at 122, is so close to the amplitude at the two superimposed input voltages to the dif- ferential point of the pulse that it can be used as a differential amplifier for all purposes. The integral curve is around one so that it can be viewed in the same way.
Adjusted the scale factor so that at the time i3 its amplitude AMP. A is the same. Although the classifying circuit 134 can now use the integral curve 90 at the point in time ti starts 45 with greater accuracy than if the pulses and the particle pulse 52 are at the point in time ti , the only loss of the area below is 52 without determining the amplitude at the center the curve 52 of the pulses would be processed unchanged,
between il and ti. The level of the threshold voltage output 126 from the multivibrator 114 is voltage 58 is actually quite small, and the use of this to reset the integrator 74 and the bistable pre-display was only for better understanding 50 direction 66, which makes the noise exaggerated drawn. is caused to return to its waiting state.

The differential amplifier 82 measures the reverse until the pulse has subsided and the next pulse between the two pulses 54 and 90 crosses the threshold 58 and a new measured point 80, 46 of FIG. 3, and as a result initiates the operating cycle . The signal 116 appears, the output voltage at 92c appears as the combined 55 of the line 126, and its trailing edge is converted into a set curve which is shown at point 92 in FIG. 3 by a suitable trailing edge detector 128. This curve has a first part 96, stent, and then appears as a pulse 130 in which passes through zero at 98 at time i3. One reset channel 132. According to this trigger pulse 130, the curve has a steeply rising part, intersects the integrator 74 along the reset path 100 and then ends at 102 derivation 100 of the curves, as in FIG. 3 shown from.
corresponding to the trailing edge of pulse 52. The falling line 100 is shown in FIGS. 5 and 6 , similar to the integral curve portions of the invention that are present at output 122 for reference 76 and 90 in the preceding graphs the classification circuit generates a position of FIG. 3. Pulse 124 'which has the amplitude AMP. A has

Lines 65 lead to an electronic switch 104 but have a much longer duration than in FIG. 3.

lines 92 and 60. Only if there is an output signal So the classification circuit 134 'can slow down

of the threshold circuit 56 is present, the function as that circuit 134, which the pulse

electronic switch 104 has to process any signals to 124 according to FIG.

The advantages of this second form of the invention can easily be seen by modifying a few achieve the coupling lines to influence the timing of parts of the device and also to use pulse 52 as a direct amplitude input to output switch 120 avoid.

In so far as the structure of the two forms of the invention is almost the same, only the differences are described and changes are noted by new or "prime" reference characters. The line 44 'now begins at the output of the scale factor setting circuit 78, so that the pulse generating device 4 © is no longer directly connected to the electronic precision switch 120. The reset line 132 is no longer connected to the bistable device 66 . But a second reset line 136 couples a reset

pulse 138 from sensing circuit 108 back to bistable device 66.

The addition of the new reset causes the bistable device to reset and thereby interrupt further operation of the integrator 74 before the integrator is reset. Therefore, the output 90 'from the integrator remains at the value AMP. A is the same throughout the duration of the signal 116 'through the multivibrator 114', all of which is shown in FIG.

To achieve the desired longer output pulse 124 ', the duration of pulse 116 is from the multivibrator 114 'is considerably longer than the previously described pulse 116 shown in FIG is. Upon termination of the pulse 116 ', the integrator is turned on by the feedback pulse 130 in reset in the same manner as in the first described embodiment of the invention.

For this purpose 2 sheets of drawings

Claims (14)

Patent claims: 1. Procedure for the height analysis of electrical impulses that are close to their rise and / or or falling edge have glitches, in particular electrical pulses from a particle counter according to the Coulter principle, characterized in that each to be analyzed Impulse is integrated that the voltage of the impulse to be analyzed and the trains- ίο associated integrated pulse voltage can be compared with each other and if the pulse value is equal and integral value a sample of predetermined short duration of the amplitude of the to be analyzed or the integrated pulse (52 to 90 ') at this point in time, which is approximately the temporal center of the pulse is marked, taken and used as measurement information of the amplitude value is forwarded. 2. The method according to claim 1, characterized in that after reaching the same value of the integral value and the pulse value a resetting of the element integrating the signal is made and this is made ready for operation again. 3. Circuit arrangement for performing the method according to claim 1 or 2, characterized in that an integrator (74) is provided to which the pulses to be analyzed (52) are fed, that each pulse to be analyzed and the associated integral curve (76) of a comparison stage (82) are supplied so that a first switch (120) is provided which briefly switches through the corresponding part of the directly supplied pulse to be analyzed (52) or the integrated pulse (9O ^{7) when the amplitude value of the pulse to be analyzed and the integrated pulse have the same amplitude} . 4. Circuit arrangement according to claim 3, characterized in that after the comparison stage (82) a feedback path (126, 132) is branched off and led to the integration stage (74), which causes it to be reset after reaching the same value between the integral value and the pulse value. 5. Circuit arrangement according to claim 3 or 4, characterized in that a threshold circuit (56) is present which is connected so that it directly receives each pulse (52) and responds to each pulse (52) which goes beyond a given threshold value, and that a second switch (68) is provided which is connected between the threshold circuit (56) and the comparison circuit (74, 78, 82) , said second switch only allowing those pulses to pass to the comparison circuit which exceed the threshold voltage of the threshold circuit ( 56) exceeds. 6. Circuit arrangement according to one of claims 3 to 5, characterized in that with the integrator (70) a scale factor setting circuit (78) is connected to the up to Set the time of the pulse center integrated voltage largely so that it is equal to the Is the voltage of the pulse which is present at the integrator input (72) at this point in time, and that an arrangement for determining the voltage difference between the pulse value and the integral value is provided, which responds when the minimum of the difference is reached and a gate signal (98) generated. 7. Circuit arrangement according to claim 6, characterized in that the arrangement for determining the voltage difference contains a differential amplifier (82) and the downstream units contain a sensing circuit (108) which receives the gate signal (98) and responds when the gate signal has a minimum value Has. 8. Circuit arrangement according to claim 7, characterized in that a multivibrator (114; 114 ') is provided which is switched on between said sensing circuit (108) and the first switch (120) , the multivibrator having a control signal (116; 116') ) generated for the switch (120) of a predetermined short duration. 9. Circuit arrangement according to claim 8, characterized in that the trailing edge of the control signal (116; 116 ') of said multivibrator (114; 114') is also fed to the integrator (74) and serves to reset it. 10. Circuit arrangement according to one of claims 7 to 9, characterized in that a gate circuit (104) is connected between the differential amplifier (82) and the sensing circuit (108) , this gate circuit being controlled by the response (64) of the threshold circuit (56) for the duration (ti to * 4) that the threshold voltage is exceeded by the respective pulse (52) to be measured. 11. Circuit arrangement according to one of claims 5 to 10, characterized in that a bistable device (66) is present between the threshold circuit (56) and the second switch (68) is on, so that this switch is only from the leading edge of the The signal that exceeds the threshold voltage is closed. 12. Circuit arrangement according to claim 11, characterized in that the control signal (116) for the first switch (120) from said multivibrator (114) is also supplied to the bistable device (66) as a reset signal. 13. Circuit arrangement according to claim 12, characterized in that the response signal of the sensing circuit (108) is fed to the bistable device to reset it. 14. Circuit arrangement according to one of claims 3 to 13, characterized in that each pulse (52) is derived from a device (40) which has an electrical path extending through a fine opening of a certain length, the central part of said path being the Central portion of each of the pulses (52) is assigned and each pulse (52) is generated by a particle suspended in a medium which traverses the path for a period of time equal to the duration of the pulse (52), the device being the input portion of a Particle analysis and sizing system, which further comprises pulse classification circuitry (134; 134 ') coupled to the output (122) of the circuit for determining the amplitude at the center of the pulse.