CS277187B6 - Device for compensating computer losses of detection systems - Google Patents

Abstract

Device for compensating counting losses of detection systems, where the output of the detection system /1/ is connected to both the input of a pulse counter /2/ and the input of a time interval meter /3/. The output pulses of the detection system are counted during the measurement and at the same time the intervals between two consecutive pulses are measured, from which the shortest time pulse is selected and its length is considered as an approximate value of the applicable dead time and is used to make a correction for counting losses.

Description

The invention relates to a device for compensating for the counting losses caused by the dead time of a detection system, which solves the problem of detecting and measuring ionizing radiation.

Prior art

It is known that all pulse ionizing radiation detectors are characterized by a certain dead time, i.e. the time interval following each recorded particle, during which the detector is not able to register other particles. This type of dead time, also called non-cumulative dead time, is especially characteristic of Geiger-Müller computers. In practice, there may be rare cases of dead time, which are characterized by the cumulative nature of dead time. In this case, each input stimulus that would normally be registered will always cause a re-extension of the dead period corresponding to the respective cumulative dead time. The described method of compensating for counting losses can generally be applied only in the case of non-cumulative dead time, but in the case of small counting losses, this method can also be used for systems characterized by cumulative dead time. .

Regarding the factors on which the dead time of the detection system depends, it should be borne in mind that in addition to the detector itself, the size of the dead time of the detection system is to some extent influenced by the parameters of some parts and the measured frequency. It is obvious that the supply voltage of the detector, the amplification of the amplifier and the setting of the discriminant level of the amplitude selector will affect the dead time of the respective detection system. As the results of numerous measurements show, the dead time also changes as the frequency of the detected particles changes.

At higher pulse frequencies, detection systems characterized by dead time always result in certain computational losses. These losses are given by the difference between the actual pulse frequency n and the measured pulse frequency m, where n - m = n.m.'T, _____ í where ^ is the non-cumulative dead time of the considered system.

Computational losses are often expressed in%, ie n - m n.

δ _η = ------ loo% = -------— loo%, η 1 + η. υ where the relationship between us is given by a known relationship

by which the measured frequency can be converted to the actual frequency, provided that we know the dead time * 77. In a similar way, a correction relationship can be written between the total number of pulses M measured in the time interval T and the actual number of pulses N corresponding to the same time interval.

M. T. N = -------___. . T - Μ .X

Corrections for calculation losses can be made in basically two ways:

The first is that on the basis of the measured values m and M, respectively, we determine the value of the actual frequency n or the actual number of pulses N using the above-mentioned relations.

The second possibility of obtaining information about the actual number of pulses is based on the use of special electronic circuits that convert the measured frequency m directly to the actual frequency n. These circuits can work as analog and are then part of analog frequency meters or as digital. In this case, the measured frequency m is fed to the input of the digital correction circuit, while a sequence of pulses representing the actual frequency n can be taken from its output.

Both of the described methods of introducing dead time correction assume that we know the actual dead time of a given detection system. There are several methods of determining dead time that are commonly used in practice. These are mainly the following methods:

The method of two radioactive emitters - dead time is determined on the basis of the measurement result of each of these emitters separately: and the measurement of both emitters together. The activity of the individual emitters is chosen to be approximately the same and is selected so that the effect of dead time is practically not applied when measuring with one such emitter, while in response to both emitters measured simultaneously, the losses due to dead time would be noticeable. A certain disadvantage of this method of determining the dead time is the relatively low accuracy due to the fact that in the simultaneous measurement of both emitters the scattering of radiation can be applied in an indefinable way and also because the measurement result is obtained from a relationship that contains a difference of two approximately equal values. statistical fluctuations.

The dead time of the detection system can also be determined by measuring with a single radioactive emitter with a short half-life. This method of measuring dead time is based on the known - exponential - course of the time dependence of the actual frequency of pulses. The actual measurement is performed gradually in several time intervals. It is obvious that at the beginning, when the measured frequency is still quite high, the effect of the dead time on the loss computer will be marked, while later it will not be substantially applied. The required dead time can then be determined by a suitable graphical representation of the measured data and their interpolation. In addition to the demanding and relatively complicated measurement, the disadvantage of this method of determining the dead time is also the need to use a radionuclide with a very short half-life. Due to the fact that the emitter of such properties is not commonly available in the workplace, because its preparation requires access to relatively strong neutron sources, the use of this method is considerably limited.

To determine the dead time, it is also possible to use some regularities associated with the dependence of statistical fluctuations of pulses repeatedly measured in a large number of the same time intervals. However, such a method is quite lengthy and complicated, both in terms of the measurement itself and in terms of evaluating the results, thus suffering from its operability.

A common disadvantage of the described devices and methods for determining the dead time of detection systems can clearly be considered the fact that the value of dead time obtained by these methods, ie on the basis of special measurements, which usually precede the actual measurement, may well correspond to the conditions under which it was determined. just as well, this value may generally differ from the value corresponding to the actual measurement or experiment conditions. This is mainly because the dead time depends in some way not only on the parameters of the detection system, but also on the values of the measured frequency.

The essence of the invention

The above-mentioned shortcomings and problems associated with the devices used so far and methods of compensating for counting losses based on dead time determination and subsequent correction eliminating the effect of dead time on the measured number of pulses are eliminated by the device according to the invention. to the input of the pulse counter and to the time interval meter. The time interval meter can be formed of a bistable flip-flop circuit connected as a frequency divider, one output of which is connected to one input of the first AND logic gate and at the same time to the first input of a digital comparator and whose second output is connected to one input of the second AND logic gate. the second input of the digital comparator. The second input of the first AND logic gate and the second input of the second AND logic gate are connected to the output of the high frequency pulse generator. The output of the first AND logic gate is connected to the input of the first pulse counter and the output of the second AND logic gate is connected to the input of the second pulse counter. The digital comparator is connected to the first and second counters and to the register.

The device works on the principle of approximating the dead time of the detection system using the shortest time interval between two consecutive pulses at the output of the system during the actual measurement. The calculations performed showed that the number of time intervals to be examined in order to find the smallest interval between them, which would sufficiently approximate the applied dead time, is not very high and corresponds roughly to the number of pulses under normal measurements. In practice, as is known, in conventional measurements, preselections of the number of pulses are used with regard to achieving a satisfactory accuracy given mainly by statistical fluctuations. The device allows the use of appropriate correction relations, with the value of the shortest time interval between adjacent output pulses of the detection system being substituted instead of the dead time. The value of this shortest time interval is obtained by evaluating the output pulse sequence during the actual measurement.

The main advantages of the device for compensating for the counting losses of the detection systems according to the invention can be seen in particular in the following facts. No further measurements are needed to determine the relevant corrections, the parameter necessary to make these corrections is obtained during the actual measurement. Corrections for counting losses do not depend on the actual frequency or on the setting of the parameters of the detection system and no prior knowledge of the size of the dead time is required. In view of the above-mentioned advantages, the use of the device according to the invention can decisively increase the quality and reliability of the measurement of ionizing radiation by means of conventional detection systems provided with a device for evaluating time intervals.

Overview of pictures in the drawing

The invention will be explained in more detail with the aid of the accompanying drawings, in which FIG. 1 shows a block diagram of the arrangement of the basic device and FIG. 2 shows an example of one possible implementation of a specific connection of a time interval meter for this device.

Examples of embodiments of the invention

The input of the pulse counter 2 and the time interval meter 2 are connected to the output of the detection system 1. The output pulses from the detection system 1 are thus fed to the pulse counter 2, which after the measurement gives information about the number of measured pulses M, and to the time interval meter 2, whose main function is to determine the shortest time interval between two consecutive pulses of the set M. Based on the measured values M and the length of the shortest time interval T _n , a corrected number of pulses N ^ is obtained according to the relation ^M ' ^T n, „

N-j. = ---, where

T - M. T _n where T is the measurement time.

It is obvious that if the number of registered pulses, and thus the total number of investigated time intervals, is large enough, the value of T _n will be close to the value of the dead time so that the difference between N _n and the actual number of pulses N will be negligible. If the measured quantity is the frequency of pulses, ie the counter of 2 pulses, or the frequency meter placed in its place, indicates the value of the measured frequency m, then the actual frequency n can be obtained using an analogous relation m

ⁿ k ^- - '

- m. T _n where n ^ -? n at T _n ->.

The specific design of a time interval meter that meets the requirements for determining the dead time correction can vary considerably depending on the principle chosen and the electronic circuits used. An example of one of the possible embodiments of the time interval meter 3 ', allowing to determine the length of the shortest interval, is shown in Fig. 2. The time interval meter 3 here consists of a bistable flip-flop 4 connected as a frequency divider, one output of which is connected to one input of the first. The second output of the bistable flip-flop 4 is connected to one input of the second logic gate 6 AND and at the same time to the second input of the digital comparator 9. The second inputs of the logic gates 5 and 6 are the output of the 11-pulse high-frequency generator is connected. The output of the first logic gate 5 AND is connected to the input of the first pulse counter 7 and the output of the second logic gate 6. AND is connected to the input of the second pulse counter 8. The digital comparator 9 is connected to both the first and second pulse counters 7 and 8 and to the register 10. The input pulse train taken from the detection unit is fed to a bistable flip-flop 4, which is connected as a frequency divider. The length of its output pulses ensures the control of the first and second logic gates 5 and 6. AND, to the second input of which pulses from the high-frequency pulse generator 11 are fed. The first counter ’Z of pulses counts the number of pulses at the output of the first logic gate 5 AND, and similarly the second pulse counter 8 serves to register the pulses that appear at the output of the second logic gate 6 AND. After each input pulse, the contents of the individual counter of Z / Z pulses are successively compared in the digital comparator 9 with the contents of register 10. If the contents of register 10 are equal to or greater than the contents of the respective counter Z or 8 pulses are transferred to register 10. After each such comparison Z counter or 8 pulses with the contents of register 10, the given Z / Z counter is reset.

Industrial applicability

The device according to the invention finds application wherever detection systems are used to measure the parameters of ionizing radiation or to determine other quantities characterizing the radiation source or the result of the interaction of the radiation with the substance. The invention is particularly suitable for detection systems characterized by a non-cumulative dead time type. In the case of lower computational losses, ie when the product n and ΐ is small enough so that η.'ΤΓ «1, the device can also be used for detection systems with cumulative dead time. Another possible application is also analog digital converters, which are generally characterized by the non-cumulative character of the dead time.

Claims (2)

Device for compensating for counting losses of detection systems, characterized in that the output of the detection system (1) is connected on the one hand to the input of the pulse counter (2) and on the other hand to the input of the time interval meter (3). 2. Device according to claim 1, characterized in that the time interval meter / 3 / is formed by a bistable flip-flop circuit / 4 / connected as a frequency divider, one output of which is connected to one input of the first logic gate / 5 / AND and at the same time to the first input of a digital comparator / 9 / and whose second output is connected to one input of the second logic gate / 6 / AND and at the same time to the second input of the digital comparator / 9 /, the second input of the first logic gate / 5 / AND and the second input of the second logic gate / 6 / AND are connected to the output of a high-frequency pulse generator / 11 /, where the output of the first logic gate / 5 / AND is connected to the input of the first pulse counter / 7 / and the output of the second logic gate / 6 / AND is connected to the input of the second counter / 8 / pulses, the digital comparator / 9 / being connected on the one hand to the first pulse counter / 7 /, on the other hand to the second pulse counter / 8 / and on the other hand to the register / 10 /.