DE2253758B2 - PARTICLE ANALYZER - Google Patents

Description

IO

The invention relates to a particle analyzer of the \ π. The preamble of claim 1 described, from US-PS 35 57 352 known art

Particle analysis often aims to fine-tune the size distribution of the particles in a given amount of a sample divided material or from particles suspended in a fluid. Uni an advertisement of the To obtain the size distribution of the particles in the amount of sample, this is determined by a particle analyzer (For example, a Coulter particle analyzer according to US Pat. No. 3,557,352). The particle analyzer generates signals in the form of pulses, the amplitude of which depends on the size of the measured or detected Particle is related. To determine the number of particles in a certain range of particles If the impulses are fed to several so-called "window comparators" each of the impulses detect that lie between a certain lower and upper threshold level, which leads to a are related to a certain particle size range. When a particle is found, its If the maximum amplitude is between the threshold levels, the respective window comparator generates an output pulse with a certain amplitude. The output pulses of the window comparators are supplied to individual accumulators or memories. The output signal level of each memory changes, i. H. increases over time with incoming pulses and therefore serves as a measure of the number of in one certain particle size range measured particles. The memories are sequentially in a previously specific sequence connected to a display device, for example an oscilloscope, the optically displays a particle size distribution curve in Cartesian coordinates. In the diagram shown the horizontal or x-axis represents the particle size and the vertical or y-axis represents the particle size The amount of particles that have entered. For the cyclical connection of the memory with the visual display device For example, an electronic control device is used in the specified sequence, see above that successive curves are displayed or written on the visual display device. As the number of particles measured increases, the maximum amplitude of each curve increases until the the specified amount of sample has run through the particle analyzer. At that time, the written Curve represents the particle size distribution curve for the amount of sample.

The increase in the amplitude of the recorded particle distribution curve takes some time, during which, however, the curve retains its overall shape. Because in most cases the sample is one contains a homogeneous mixture of particles of different sizes, the size distribution curve is for different amounts of the sample are essentially the same. Therefore, after a sufficiently large, sample amount representative of the particle distribution curve has flowed through the device, the curve for various purposes can be viewed in full scale of the visual display device. This is for example then possible if it can be determined immediately whether the sample analysis is being carried out in the right way will expire

With the particle analysis devices available up to now a control button (gain control) and / or a range switch on the visual display device adjusted be reduced. This is done manually and repeatedly while analyzing the chosen Amount of sample while the data is entering the memories. This time can range from a few seconds up to four or five minutes or longer.

As soon as a curve representative of the distribution of the sample is available, the sample distribution curve should be be integrated, so that an integral curve, usually in the form of an S or a slope, results. The integral curve is then used to determine the relative concentration of the particles in a given Particle area analyzed In order to be able to carry out this analysis quickly, the maximum amplitude of the integral curve to an amplitude equal to 100% on the scale of the screen of the visual indicator can be set. The other points of the integral curve with lower amplitude are then equivalent to the relative concentration of the particles within a certain range. Currently is for these adjustments take a significant amount of time to achieve a relatively accurate visual display of the in a point in time that has been accrued, which depends on the experience of the operator.

The possibility of accessing the data at any time and regardless of the actual data Representing amount of data on a full scale is especially useful for industrial and commercial users medical application area desirable, for example in the monitoring of growth of crystals, particle compositions, in pharmacy and hematology, where the relative comparison must be done quickly and accurately between data.

In order to obtain the desired display, an apparatus must be provided which, if sufficient Data is available, the evolving data distribution curve is amplified and the integral forms the same on the full scale of the visual indicator. The device must have the Set the gain automatically, i.e. lower it as more and more data is analyzed, see above that the height or maximum amplitude of the size distribution curve and the integral thereof are substantially remains constant, although the course can change slightly during the entry of the data.

It is therefore a device for the automatic ί- "· ', division of the amplitude of a data distribution curve lui · a small proportion of the incoming data be created so that the full-scale curve over a substantial portion of the field of view of the visual indicator can be displayed, regardless of the amount of up to this Time of incoming data.

It is also intended to provide a device for automatically keeping the maximum amplitude of the integral constant the data distribution curve at 100% on the scale of the

Screen of the visual display device, the linear proportionality of the on the The data distribution curve displayed on the screen should be kept constant.

From US-PS 32 04 144 an amplifier circuit for adapting the image size of a signal to a given format is already known, which contains an amplifier and an input attenuation circuit for the amplifier, which is variable as a result of the above or below a reference voltage However, this amplifier circuit in a particle analyzer would make its structure and function relatively complicated, because in this the signals to be further processed arrive on different channels.

The invention is therefore based on the object of creating a particle analyzer with which after a few data has come in on the individual channels, those on the screen of the visual display device curve to be displayed can be displayed in full scale.

This object is achieved according to the invention by the measures covered by claim 1

Preferred developments and configurations of the particle analyzer according to the invention are the subject matter of the subclaims 2 to 17.

The invention is explained in more detail with the aid of the preferred exemplary embodiments shown in the drawing explained it shows

F i g. 1 shows the schematic block diagram of a particle analyzer with a gain control circuit,

F i g. 2 is a diagram showing a particle size distribution curve and the integral curve thereof as displayed on the oscilloscope screen will,

3 shows the schematic circuit diagram of an exemplary embodiment the gain control device, the gain control taking place in that the Input signal to an amplifier is lowered or attenuated.

4 shows a series of diagrams over the same time scale with the voltage curves various points of the circuit of the gain control device the F i g. 3 during different modes of operation of the same,

5 shows the schematic circuit diagram of a second Embodiment of the gain control device, in which the gain control by change the impedance in the gain control circuit of a Amplifier takes place

6 shows the schematic circuit diagram of a third exemplary embodiment of the gain control device, in which the gain control takes place by means of digital lowering and / or attenuation of the input signal of an amplifier and

FIG. 7 is a series of diagrams on the same time scale showing the voltage gradients at different points in the circuit of the amplification control device of FIG. 6 during different modes of operation of the same.

The in F i g. 1 shown in a schematic block diagram particle analyzer contains a pulse amplitude auriysator 10. The analyzer 10 comprises a Teflchenmnalysator, for example a Coulter particle analyzer, in which a sample amount containing several particles is passed through a measuring zone in which each particle is measured and a signal in the form of a Particle impulse is generated, the amplitude of which is related to its size or volume. The particle impulses are each fed to a pulse amplitude discriminator, which contains several so-called "window comparators".

The window comparators measure particle pulses whose amplitude is between a predetermined lower and a predetermined upper threshold level. If a particle pulse is measured, its amplitude between the predetermined

, o lower and upper threshold level falls so the generated respective window comparator an output pulse.

The window comparators are via individual separate channels with an accumulator, memory or Integrator of an information storage device 12

ij connected. The channels connecting the window comparators to the associated memory are denoted by a dashed line 14.

The memories of the storage device 12 are each through a separate and single channel with individual

ίο electronic switches of a channel selector 16 connected. The channels connecting the memories to the electronic switches are indicated by a dashed line 18. The memories are furthermore each represented by a separate and individual channel with a single one electronic switch of an integrator 20 connected. The memory with the electronic switches of the Integrator's connecting channels are shown in FIG. 1 represented by a dashed line 22 The output of the Channel selector is via a line 24 with a

jo gain controller 26 connected. The outcome of the Integrator 20 is also connected to gain controller 26 via a line 28. The output signal of the gain controller can not use a line 32 to an amplifier 30 for the y-axis oscillograph shown and / or via a line 36 to an amplifier 34 for the y-axis of a not are fed to the recorder shown.

An electronic control device 38 is connected via lines 40, 42 and 44 to the channel selector 16, the integrator 20 and the gain controller 26, respectively. The electronic control device 38 is also connected via a line 46 to the control device 48 for the horizontal deflection of the oscilloscope and / or the recorder.

The electronic control device controls the closure of the electronic switches in the channel selector 16 and in the integrator 20, so that when the electronic control device acts on the switches in the channel selector 16, the channels 18 are each connected to the output conductor 24 sequentially in a predetermined order for a certain time will. In this way, the electronic control device to the. ^ Axis amplifiers 30 of the oscilloscope signals are supplied by. At the same time controls the

Electronic control device 38, the Horizontalab steering control 48 and thus the horizontal deflection of the oscilloscope in a temporal relationship to the work of the channel selector 16. For example , for a first time period, which corresponds to a part of the period of the horizontal deflection, the electronic control device 38 prevents a first channel The information storage device 12 with the output conductor 24. In the case of a particle analyzer, this initially drives an output signal level that is a measure of 6s the number of particles measured, the size of which falls within a first particle size range, for example between 0 and 1 μ connects the control device for a second period of time, the same

is the first period of time, a second channel with an output signal level from a memory in the Information storage device having output conductor 24. This second output signal level is a measure for the number of particles with a size within a second range, for example between 1 and 2 μ. The electronic control device 38 further connects sequentially in a specific order and for a certain time the various channels 18 with the output conductor.

If the gain controller 26 is initially omitted, the y-axis amplifier 30 of the will appear Output signal level fed to the oscilloscope as a point on the oscilloscope screen. Several by the timed supply of the output signal levels to the amplifier 30 form points a curve on the oscilloscope screen, known as a differential curve or particle size distribution curve referred to as. These in FIG. 2 particle distribution or differential curve denoted by 50 results from several points, of which three points 51.52 and 53 are shown.

The integral curve of the particle distribution curve 50 results from the selective addition of the output signal levels of the channels 22 in a predetermined order and at predetermined time intervals. This is done with the aid of the electronic control device 38, which initially has a first switch in the Actuates or closes integrator 20, which the first Kana! of the first memory in the information storage device connects to the exit letter 28. The switch remains for the entire time period of the horizontal deflection closed. After a predetermined time, the electronic control device closes a second switch in integrator 20 for connection a second channel of the memory device 12 with the conductor 28. The switch remains for the period of Horizontal deflection closed. The electronic control device then closes the other Schaller of the integrator 20 and keeps it closed, so that sequentially the other channels of the channel 22 with the Output conductor 28 are connected. In this way, the oscilloscope screen displays the information shown in FIG. 2 The integra curve labeled 60 was recorded.

The electronic control device operates the electronic switches in the channel selectors 16 and 20 cyclically and sequentially. Furthermore, the electronic control device changes what is shown below with reference to FIGS. 3 and 4, the circuit connection in the gain controller cyclically so that it works according to one of several modes of operation or programs so that increasing output signal levels result on the channels 18 and 22 , the channel selector 16, the integrator 20 and the gain controller 26 cyclically, in time relation to the horizontal deflection of the oscilloscope or recorder.

Accordingly, during the analysis and storage of the data, the amount of data entered at different times during the analysis of all data is displayed on the oscilloscope while the particles are measured and the output pulses are stored in the memories or accumulators, the control device 38 closes cyclically and sequentially Switch in the channel selector 16 so that the developing particle size distribution curve for a given amount of sample is continuously and automatically recorded on the screen of the oscilloscope, as indicated by the dashed curves 61 to 64 in FIG. After the sample has passed through the particle analyzer, the output signal level of each of the channels 18 from the memories in the storage device 12 reaches a final value so that subsequent recordings of the particle distribution curve on the oscilloscope form curve 50. At the same time, the integral curve for the particle distribution curve 50 is that in FIG. Curve 60 shown in 2.

The growth of the particle distribution curve on the screen, its amplitude increasing, increases to take some time. The overall shape remains the same. Since in most cases the analyzed data, For example, a given sample amount containing particles contains a homogeneous data mixture, the size distribution is essentially the same for different parts of the total data set. To the analysis of one to generate one for the sample distribution curve of the total amount of to

J ₅ analyzing data representing a representative amount of data, for example to generate curve 61, it is desirable to immediately amplify curve 61 to the size of curve 50. In particular, it is important to amplify the integral of curve 61 to the amplitude of curve 60. The gain controller is activated cyclically and cyclically and automatically adjusts the gain of an amplifier contained therein to amplify the increasing curves, for example curves 61 to 64 to the level of curve 50.

As shown in FIG. 3 and 4, this is done by amplifying the maximum amplitude of the integral curve of each intermediate curve of the data distribution curve, for example curve 61, to an amplitude of 100% of the scale of the oscilloscope screen. It is thus amplified to a maximum amplitude which is the same as the maximum amplitude of curve 60. Typically, the actuation of the integrator is reversed by electronic control device 38, so that the mirror image of curve 60 shown in broken lines in FIG. 2 is generated. This mirrored or inverted integral curve 70 is preferred because the operator can select a certain percentage value, for example 75%, and read off the curve 70 on the y-scale and determine that 75% of the particles are larger than size A.

The preferred embodiment of the gain controller 26 shown in FIG. 3 includes an amplifier 74 with a gain control circuit 76. The gain control circuit 76 includes two resistors connected between the output 78 of the amplifier 74 and a common conductor 80 connected to the common ground of the device 26. A feedback line 82 is connected between the connection between the two resistors and one input 84 of the amplifier 74. The signals on the line 24 are fed to the other input 90 of the amplifier 74 at predetermined times via a switch 86 and the attenuation circuit 88

6s The attenuation circuit 88 contains a resistor 92 which is connected between the switch 86 and the input 90 is connected, as well as a voltage-dependent resistor 94, which in the embodiment selected here

709 512/214

example consists of a field effect transistor%. The channel selector 16 contains a feedback circuit S8 between the output 78 of the amplifier 74 and the gate 100 of the field effect transistor 96. The drain 102 of the transistor 96 is connected to the input 90 and the source 104 is connected to a zero balance circuit 106.

The feedback circuit 98 contains a comparator 108. One input HO of the comparator 108 is connected to the output 78 of the amplifier 74, and the other input 112 is connected to a reference voltage source 114 . The output 116 of the comparator 108 is selectively connected via a switch 118 to a capacitor 120 and the gate 100 of the transistor%. The capacitor 120 serves as a memory for storing a correction signal which occurs at the output 116 of the comparator 108 . The correction signal is held on connection 121 . The zero compensation circuit 106 contains a comparator 122. One input 124 of the comparator 122 ict is connected to the common conductor 80 . The other input 126 of the comparator 122 can be connected to the output 78 of the amplifier 74 via a current limiting resistor 128 and an electronic switch 130. The comparator 122 is connected as an operational amplifier to a capacitor 132 which is connected between the input 126 and the output 134 of the comparator 122 . The output 134 is also connected to the source 104 of the transistor 96.

Based on the F i g. 1, 3 and 4, a preferred mode of operation of the gain controller 26 will now be explained. As mentioned, the electronic control device 38 controls the gain controller 26. For this purpose, the control device 38 can control the switches 86, 118 and 130 in a predetermined manner so that the gain controller 26 can run in four modes of operation or programs. These modes of operation are denoted by I to IV in FIG. The modes of operation or programs run during a time which is equal to one horizontal deflection period of the oscilloscope.

In Fig. 4, diagram A shows the signals which are fed to the gain controller 26 by the channel selector 16 or the integrator 20. In the first program, a differential curve 138 is fed to the gain controller 26. In the second program, an integral curve 140 of the curve 138 is fed to the gain controller 26. In the third and fourth programs, the control device 38 closes the electronic switches in the integrator 20 so that the maximum amplitude 142 of the integral curve is fed to the gain controller (diagram A in FIG. 4 ). The diagram B of F i g. Figure 4 illustrates the signal applied to the input 90 of the amplifier 74 during the four programs of the gain controller 26. Diagram C is the signal at the output 78 of the amplifier during the same time period. Diagram D shows the voltage stored in capacitor 132 of zero equalization or correction circuit 106. The diagram .Eist the voltage occurring at the connection point 121 between the capacitor 120 and the gate 100. Diagram E shows a negative voltage which increases to zero when the attenuation of the voltage-dependent resistor 94, ie. of the field effect transistor 96 should be increased

From the diagrams A, B and C of Figure 4 it can be seen that during the first mode of operation of the

Vei strengthening controller are the differential distribution curve or representative signals passed 26 through the gain controller 26 to the oscilloscope. The input differential signal in diagram C is denoted by 144 and the output differential signal in diagram C is denoted by 146. In the other mode of operation of the gain controller 26 , the signal representing the integral of the differential signal 138 is passed through the gain controller 26 to the oscilloscope ίο. The input integral signal is denoted by 14JJ in diagram B and the output integral signal in diagram C by 1:50 . During the first two modes of operation of the gain regulator 26 , the controller 38 supplies signals to the switches 86, 118 and 1-IO via the conductor 44 so that the switch 86 is held in the position in which it connects the conductor 24 to the resistor 92 and switches 118 and 130 are open. At the beginning of the third mode of operation of the gain controller 26, the switch 86 is actuated and the resistor 92 is thus connected to ground. At the same time, the switch 130 is actuated, which connects the output 78 via the resistor 128 to the input 126 of the comparator 122. This third mode of operation can be referred to as a zero correction cycle. In this case, a zero input signal is fed from the common conductor 80 via the resistor 92 to the input 90.The signal w.rd occurring at the output 78 is compared by means of the comparator 122 with the common potential on the common conductor 80 that is connected to the input 124 of the comparator 122 connected is. In other words, when ground potential is present at input 90 of amplifier 74, a signal with approximately ground potential is emitted at output 78. The signal at the output 78 cannot be exactly the same as ground potential, since a small voltage difference arises in the amplifier, for example as a result of the drift of voltage settings in the amplifier 74. If the output 7 'does not have a ground potential, the comparator 122 operates as an integrator, whereby the resistor 128 acts as a current limiter and the capacitor 132 acts as a memory. The capacitor 132 then charges to the voltage present at the output 78 and holds this voltage until the third mode of operation is repeated. The voltage across the capacitor 132 is also on the κΤιι. α ^{an And determines} the voltage level above which all information is processed. In other words, the voltage on capacitor 132 determines the zero level. The zero peso ^ input signal to the input 90 of the amplifier 74 is denoted by 152 in the diagram. The zero output level at the output 78 is denoted by 154 in diagram C. The zero correction or equalization signal is denoted by 156 in diagram D This is you at the output 134 of the comparator 122 occurring signal.

In the fourth mode of operation of the gain regulator, the control device 38 switches on the switch «β, which connects the conductor 24 to the resistor 92. Furthermore, the switch 132 is opened and the switch« o 118, which connects the output 116 of the comparator «V? ^the . ^Condensation ator 120 and the gate 100 connects the same time, as described above, the maxima of the input signal amplitude, namely the integral Mioamalamphtude 140 corresponding ATS 142 in the diagram Λ via the line 24 the gain

£ ^g -! FS ^ f® "* · S ^ * ^the switch 118 is closed Bt, the voltage at the output 78 of the amplifier / 4 is the reference voltage of the reference voltage source

114 is compared, and a difference or correction signal is generated at the output 116 of the comparator and fed to the capacitor 120 by the switch 118. As in diagram E of FIG. As shown in Fig. 4, the initial difference signal is a negative voltage with a negative value. As the maximum input to gain regulator 26 increases, the difference signal is such that capacitor 120 is discharged. The voltage level across the capacitor 120 is labeled Emit 158 in the diagram. At the beginning of the fourth period, the voltage 158 rises during a time T to a less negative value. The voltage level 158 is applied to the connection 121 of the capacitor with the gate 100 and the switch 118. By changing the signal 158 from a negative value to a less negative value, the resistor 94, which is variable by a voltage, attenuates or lowers the input signal to the amplifier 74 by an amount which is proportional to the increase in the maximum amplitude on the conductor 24. This voltage increase is im Diagram A of Figure 4 with e, denoted. The correction voltage or the correction signal is shown in diagram E in FIG. 4 denoted by e _c.

As a result of this correction, the maximum templitude 160 of the integral curve 148 (diagram B) is kept at the same amplitude as the previous maximum amplitude 161 (diagram B). Likewise, the maximum amplitude of the integral curve 150 (output 78 of the amplifier 74) is maintained at a maximum level 162 (diagram Q, which is the same maximum amplitude of the integral curve before the cycle of the four modes of operation (curve 163 in diagram C of FIG. 4) The output signal at the output 78 of the amplifier 74 is also equal to the voltage applied to the comparator 108. This reference voltage, as stated above, is equal to the maximum voltage at a certain scale on the screen of the oscilloscope so that the differential curve and the integral curve of the accumulated data are essentially is kept constant, while additional data enter the control device 38 during subsequent cycles. The control device 38 controls the gain controller 26 cyclically through the four programs r increases (s. Amplitude level 164 in diagram A of FIG. 4). The feedback circuit 98, however, generates a correction signal in the voltage level 158 which occurs at the junction 121, so that the attenuation by the attenuation circuit 88 is changed and the maximum input signal to the input 90 of the amplifier 74 (160a in diagram B) has the same level as the maximum signal 160 during the previous fourth mode of operation of regulator 26. Likewise, the maximum amplitude of the output signal at output 78 is kept at the same level (see 162a, 162 and 163 in diagram Q. This voltage level is equal to the reference voltage. Therefore, as soon as a significant amount of data has been analyzed, In order to generate a representative differential curve 61, the control amplifier 26 automatically amplifies the differential curve to the size of curve 50. Every fourth period of the horizontal deflection of the oscilloscope, the gain controller 26 automatically adjusts the gain of the maximum amplitude of the input signal which is fed to it, so that the ' maximum output signal of the amplifier 74, which is fed to the oscilloscope, remains constant. This maximum amplitude fed to the oscilloscope is in turn the maximum amplitude of the integral curve of the differential curve and is equal to the voltage level corresponding to 100% of the scale of the screen of the oscilloscope.

5 shows a schematic circuit diagram second embodiment of the gain controller according to the invention. The in F i g. Gain controller shown in Figure 5 226 (identical elements are denoted by the same reference numerals as in Fig. 3) includes an amplifier 74, and comparators 108 and 122. The conductor 24 is via a resistor 228 with connected to the input 90 of the amplifier 74. An electronic switch 230 is between the common Conductor 80 and input 90 of amplifier 74 are switched. The switch 2; M> is closed by the controller 38 during the third or zero reset period of the gain regulator 226 so that the Input 90 is connected to ground potential.

In the case of the gain controller 226, the output signal occurring at the output 78 is fed via a feedback circuit 234 to a connection point 236 in a gain control circuit 238 of the amplifier 74. The feedback circuit 234 contains a comparator 108, the output 116 of which is connected via a resistor 240, an electronic switch 242 and an isolating amplifier 244 to a voltage-dependent resistor 246, which in turn is connected to the connection point 236 of the common conductor 80. The gain control circuit 238 for the amplifier 74 is formed by a resistor 254 and the voltage dependent resistor 236 which are connected in series between the output 78 and the common conductor 80. The connection point 236 between the two resistors 254 and 246 is connected to the negative input 84 of the amplifier 74 via a coupling resistor 256. During operation of the feedback circuit 234, the resistance ratio of the resistors 246 and 254 can vary between 1: 1 and 1:10. When the resistor 246 changes, the gain of the amplifier 74 changes, since the potential at the junction point 236, which is fed back to the negative input 84, is also changed every time the value of the resistor 246 changes. Therefore, when switch 242 is closed during the fourth operating period of gain regulator 226, the maximum amplitude of the integral of the signal level representing the information accumulated and amplified by amplifier 74 is compared by comparator 108 with the reference voltage of reference voltage source 114. In Einei difference between these two voltages is because: the comparator at the output of 116,108 occurring difference signal supplied through the switch 242 to the gate 24J result, the Widerstandswer of the voltage-dependent resistor 246 and Dami the gain of the amplifier 74 changes until the output voltage at the output 78 The difference or correction signal is stored in a memory device or a capacitor 25) , which works in the same way as the capacitor 120 and holds the difference or correction signal at the connection point 259 , since the variable resistance was resisted by the isolating amplifier 244 246 is fed

The gain controller 226 also includes a zero correction or adjustment circuit 260 with the Comparator 122 and the capacitor 132. The NuH adjustment circuit 260 also contains a resistor 262 and an electronic switch 264 which s between the output 78 of the amplifier 74 and the Input 126 of the comparator 122 are connected in series with one another. Resistor 162 is similar to that Resistor 128 is a current limiting resistor. The electronic switch 264 works in the same way Like switch 130 of FIG. 3. Switch 264 is also in the third operating period of the Boost Government 226 is closed, so that, similar to the circuit 106 of FIG. 3, a zero correction takes place

Switches 242 and 264 are controlled by controller 38 in the same manner as switches 118 and 130 of controller 26 of FIG. 3. The gain controller 226 thus also has four operating periods which are identical to those of the controller 26. The signals shown in diagrams B and C of FIG. 4 thus represent the signals which occur at input 90 and at output 78 of amplifier 74 of circuit 226. The zero setting signal appearing at the output 134 of the comparator 122 is also fed to the negative input 84 of the amplifier 74 via a resistor 266 during the zero setting period. Resistors 256 and 266 are high-value coupling resistors. Their resistance is significantly greater than that of resistors 254 and 246 of gain control circuit 238.

F i g. 6 shows »the schematic circuit diagram of a third Gain controller 326. Here, too, similar or identical circuit elements have the same reference numerals as in the case of the control amplifier 26 in FIG. 3. The variable gain amplifier 326 contains the amplifier 74 and the gain control circuit 76 as well as the Reference voltage source 114 and the comparator 108, which forms a feedback circuit 330. Of the Gain controller 326 differs somewhat in its operation from controllers 26 or 226. The Gain controller 326 can be viewed as a digital gain controller that is stepwise or stepwise Causes (digital) changes in the amplitude of the maximum input signal fed to the amplifier 74. The gain controller 326 is also controlled by a different control circuit, other than any Control device 38 contains. In addition, gain controller 326 does not include zero correction or zero correction -Reset circuit.

The feedback circuit 330 includes an up / down counter 332 and a chain divider 334. The am Output 116 of the comparator 108 occurring difference or correction signal is an input 336 of the up / down counter 332 is fed. A further input 338 of the up / down counter 332 is fed by a Gate circuit 340 code signals supplied. The gate 340 has a clock input 342 and a marking or Control input 344 to which clock signals or control or marking signals from a control device (not shown) can be supplied via conductors 345 and 347, respectively. The output of the up / down counter 332 is via a Conductor 348 connected to several electronic switches (not shown) in chain divider 334. The chain divider 334 is connected between conductor 24 and input 90 of amplifier 74. The chain divider 334 contains a matrix of resistors that are in various combinations by the electronic switch connected in divider 334 so that the signal on conductor 24 is divided or lowered ( before it gets to entrance 90

Based on the F i g. 6 and 7, the operation of the gain controller 326 will now be described. The diagram in FIG. 7 is essentially the same as diagram A in FIG. 4 with the exception that the horizontal scale is expanded or expanded. Diagram F shows a differential curve which is fed to controller 326 during the first working period I, as well as an integral curve 350, the him during a second! Working period II is supplied. The controller 32i also works during a third working period during which the maximum amplitude 352 (diagram F of the integral curve 350 is fed to the controller 326. The third working period III is longer than the first two working periods I and II (FIG. 7). Diagram G shows the output signal at the output 78 of the amplifier 74 during the various working periods of the controller 326. The diagram H shows there: Correction signal at the output 116 of the comparator 108 The diagram / shows the control signal fed to the input 344 of the gate circuit 340 via the conductor 347. The Diagram / shows the output signal of the gate circuit 340, which is fed to the input 338 of the up / down counter 332. Diagram A shows the clock signal fed to the clock input 342 of the gate circuit 34 (via the conductor 345).

During the first operating mode or period, the differential curve 348 is amplified by the amplifier 74 zi an amplified differential curve 360 (diagram G , which occurs at the output 78 of the amplifier 74. Since the maximum amplitude of the differential signal 36C is less than the reference voltage supplied to the comparator 108, appears at the output 116 of the comparator 108 is not the difference signal designated in diagram H with 362. At the same time, the control circuit not shown has changed the control signal from level "one" to level "zero" at which it was during the first and second functional period de ;, Controller 326 (364 in diagram /), while the control signal is at "zero" level, the output signal of gate circuit 340 is also "zero" (366 in diagram J). Diagram K) of the gate circuit 340 is supplied.

At the end of the first functional period, the integral signal 350 is amplified by the amplifier 74 to a signal 368 (diagram G) . When the amplitude of the integral signal 368 reaches the reference voltage denoted by e _r in diagram G , a difference or correction signal is generated at output 116 of comparator 108. This signal is denoted by 370 in diagram H. At this time, however, the control signal is still at “zero” and there is no change, although the difference signal 370 is fed to the input 336 of the up / down counter 332. At the end of the second functional period, the control signal is switched from "zero" to "one" (372). The gate circuit 330 routes the clock signal (diagram K) to the input 338 of the counter 332 (374 in diagram J). When the counter 332 receives one of the pulses of the clock signal, at the same time as a correction signal 370 supplied to the counter 332, an output signal is generated by the counter 348, by which one or more electronic switches actuate the ladder 334, and that via the line 24 to the chain splitter 334 supplied signal is further reduced. This results in a gradual downturn.

: change in damping or damping (376 in diagram G). If the correction signal 370 is still present at the counter 332 when the subsequent clock pulse is fed to the counter 332, then another correction signal 5 is fed to the divider by the counter 332 via the line 348, so that a further step-by-step change in attenuation 378 (diagram G) occurs Likewise, if the correction signal 370 is still pending on the up / down counter 332, when a third clock pulse is fed to the counter 332, a further step-like change in attenuation 380 (diagram G) is caused lowered to a level which is below the reference voltage e _r . As a result, the correction signal 370 ends (382 in diagram H).

The comparator 108 only generates an output signal when the input 110 of the comparator 108 The supplied output voltage of the amplifier 74 is greater than that of the input 112 of the comparator 108 supplied reference voltage. Thus, although the voltage level 380 is lower than the Reference voltage, no correction signal generated. In other words, that which is now present at the output 116 and the signal applied to input 336 of counter 332 is a "zero".

The up / down counter 332 increases or decreases the attenuation or voltage division as a function of the logic signals which occur at the inputs 336 and 338. If a logic zero is present at the two inputs of the counter 532, the setting of the chain part 334 does not change. Likewise, no change occurs if a “zero” is present at input 338 and a “one” is present at input 336. However, if both inputs have “one”, then counter 332 increases the voltage drop (382 in diagram H) on Input 336. If a logical “one”, for example pulse 384 of the diagram / input 338, is fed to the attenuation or voltage drop. This lowering results in a rise 386 (diagram G) in the output signal of the amplifier 74. This output level 386 U is above the reference voltage e _r . As a result, a difference signal 388 (diagram H) is generated by the comparator 108. As a result, if the voltage level 378 is not equal to the reference voltage, the system will "swing". That is, the output of amplifier 74 fluctuates between levels 378 and 380 up and down. At the same time, the output signal 116 fluctuates between the zero level 3il2 and the signal correction level 388 (diagram H) up and down until the third operating period of the gain controller 32 € has ended. The operating periods are then repeated in the same manner as for the gain controllers 26 and 226.

For most applications, the analog gain controller 26 of FIG. 3 preferred digital gain controller 326 is preferred when a digital control system is used target.

For this purpose 4 sheets of drawings

Claims (17)

Patent claims: 1. Particle analyzer with a signal generating device with a particle sensor for generating a signal for each particle detected in a measuring zone, the signal being related to the size of the detected particle, with memories for storing signals for particles falling in different size ranges, with a visual one Display device for displaying the signal level in the various memories, and with a switching device for cyclic and automatic connection of the outputs of the memory with the visual display device, characterized by a reference spa.niringsource (.-14), the voltage of which corresponds to that on the visual display device for a specific setting of the same maximum voltage to be displayed is related by a comparison circuit (108) mounted on the Bezugsspannungsque * °: lle is connected (114) and the visual display device and the reference voltage with the amplitude of the signal displayed compares which is related to the sum of the signal levels, so that a difference signal is produced which is equal to the difference between the signal to be displayed and the reference voltage, and through an attenuation circuit (88; 238), which divides the signals to be displayed according to the difference signal. 2. Apparatus according to claim 1, characterized in that the comparison circuit (108) has a Compensator with one input (110) connected to the display device, one input to the Reference voltage source (114) connected input (112) and an output (116), at which the difference signal occurs. 3. Apparatus according to claim 2, characterized in that the damping circuit (88; 238) contains a voltage-dependent resistor (94, 246), and that the comparison circuit with the voltage-dependent resistor is connected. 4. Apparatus according to claim 3, characterized in that the voltage-dependent resistor consists of a field effect transistor (96, 246), the gate (100; 248) of which with the output of the Comparison circuit (108) is connected. 5. Device according to at least one of claims 2 to 4, characterized by a electronically controlled switch (118; 242) with a first, to the output (116) of the comparison circuit (108) connected terminal, and with a second to the attenuation circuit (88; 238) connected terminal for using the differential signal to lower the device supplied input signal, wherein the switch (118; 242) by an electronic control device (38) which closes the switch at the same time as the control device at the same time all signal levels in the memory (12) switches to the damping circuit, so that the The device's output signal is only adjusted when it has a maximum input signal is fed. 6. Apparatus according to claim 5, characterized in that the second terminal of the electronic Switch (118; 242) connected to a gate (100; 248) of the voltage-dependent resistor (94; 246) is 7. Apparatus according to claim 5 or 6, characterized by a storage device (120; 258), which is connected to the second terminal of the switch (118; 242) and for storing the difference signal and for supplying it to the attenuator circuit (88; 238) during the time the switch is open until on new differential signal is generated upon subsequent closing of the switch. 8. Apparatus according to claim 7, characterized in that the storage device consists of a Capacitor (120,258) 9. Device according to one of claims 1 to 8, characterized by one at the output of the Memory (12) connected input resistance (92; 228). 10. The device according to at least one of claims 1 to 9, characterized by a Amplifier (74) connected between the memories (12) and the visual display device 11. The device according to claim 10 characterized in that the damping circuit (8iB) with an input (90) of the amplifier (74) ve-linked. 12. Device according to one of claims 3 to 11, characterized by a zero compensation circuit (106; 260) between the visual indicator and the voltage-dependent resistor is switched. 13. Apparatus according to claim 4 and 12, characterized characterized in that the zero compensation circuit (106) between the visual display device and the source (104) of the field effect transistor (%) is switched. 14. The device according to claim 10, characterized in that the damping circuit (2315) a gain control circuit for the amplifier, and that the gain control circuit contains two resistors (24 (5, 254) between the output (78) of the amplifier (74) and the common potential for the device are connected, the one resistor (246) from a voltage-dependent resistor and the comparison circuit (108) with the voltage-dependent Resistor (246) is connected. 15. The apparatus of claim 14, characterized by a zero compensation circuit (260) which from the visual display device to an input (84) of the amplifier and the connection point between the two resistors (254,246) connected. 16. The device according to claim 1, characterized by a chain divider (334) between the Memory (12) and the visual display device is switched by an up / down counter (332) with one output connected to the chain divider (334) and two logical inputs (336, 33 (() for controlling the pitch increase signal or the pitch decrease signal sent to the divider by are fed to the counter, the comparison circuit (108) to one input of the counter (332) for feeding the difference signal to the same is connected, and by a gate circuit for the supply of clock pulses for predetermined Times to the second input of the counter (332), thereby providing the input signal to the device digital, is gradually lowered if the one Input a differential signal is supplied. 17. The device according to claim 16, characterized by one between the chain divider (334) and the visual indicator switched amplifier (74), wherein the comparison circuit (108) is connected between the output of the amplifier (74) and the up / down counter.