RU2165100C2 - Device for parametric estimation of message stream distribution mechanism - Google Patents

Abstract

FIELD: computer engineering; multichannel radio communications. SUBSTANCE: device has input amplifier, parameter and arithmetic mean computing units, type-of- distribution defining unit, distribution computer, control unit, and intensity analyzing unit. EFFECT: enhanced speed of response. 4 cl, 7 dwg

Description

 The invention relates to radio engineering and computer engineering and is intended for parametric estimation of the distribution law of multi-packet message flows in multichannel (satellite, radio relay, tropospheric) radio communications integrated into a digital integrated service communication network (ISSC).

 A device for evaluating the distribution function, containing a control device, a memory unit and a consent check unit (see ed. St. USSR N 236868, G 06 G 7/52, 1969, bull. 7).

 The disadvantage of this device is the low level of performance, since it uses the control device to sort through the set of proposed theoretical distribution functions, the values of which are stored in the memory unit, taking into account a large number of different combinations of parameters of the distribution laws. The device does not provide for any preliminary selection of the type of distribution, which makes it necessary to sort through the set of theoretical distribution functions, and, consequently, insufficient performance.

 A device is known for parametric estimation of the distribution law, comprising an input amplifier, a memory unit, a consent check unit, a control unit and a synthesizer of the distribution function (see ed. St. USSR N 1024935, G 06 F 15/36, G 06 G 7/52, 1983, bull. 23).

 However, this device has a low level of performance when used to evaluate the distribution of multi-packet message streams (MPS) in integrated service networks, due to the need to iterate over a set of M combinations of distribution parameters of a message stream consisting of many packets.

 The closest in technical essence to the claimed device (prototype) is a device for parametric evaluation of the law of distribution of message flows (see RF patent N 2094844, G 06 F 17/18, bull. 30), containing an input amplifier, the input of which is filed a binary pulse sequence, a parameter calculation unit, an arithmetic mean calculation unit, a distribution type determination unit, a distribution calculator and a control unit, the output of the input amplifier being connected to the first input of the steam calculation unit meters, the second and third inputs of which are connected respectively to the second and third outputs of the control unit, the first output of which is connected to the sixth input of the distribution calculator, the first and second outputs of the parameter calculation unit are connected respectively to the first and second inputs of the arithmetic mean value calculation unit, the first output of which connected to the first input of the distribution calculator and to the input of the distribution type determination unit, the second output of the arithmetic mean value calculation unit is connected to oromu distribution calculator entry, three output distribution type determining unit are connected to third, fourth and fifth inputs distribution calculator, whose output is an output device.

 In the prototype, an increase in speed is achieved by eliminating the need to sort through a set of M combinations of the parameters of the MPS stream distribution, as well as the ability to evaluate the law of the distribution of the MPS stream based on calculating the average values of the parameters of this stream.

 However, the prototype has a drawback - a limited scope, because it is not able to evaluate the distribution law of heterogeneous (mixed) streams of MPS occurring in the ISSC and due to the presence of a source of information in it, issuing both explicit independent user information messages (ICP) and packs of ICPs whose lengths are distributed according to a geometric law [1]. In this case, when approximating real statistics of incoming ICP flows, it is impossible to reduce them to three stream modifications that the prototype device is oriented to.

 The aim of the invention is to provide a device for parametric estimation of the law of distribution of message flows with a wider scope, a device capable of estimating the distribution parameters of both homogeneous and inhomogeneous (mixed) streams of MPS streams that periodically change their intensity during the operation of a central digital communications center.

 This goal is achieved by the fact that in a known device for parametric estimation of the law of distribution of message flows containing an input amplifier, the input of which is a binary pulse sequence, blocks for calculating parameters, calculating arithmetic mean values, determining the type of distribution, distribution calculator and control unit, clock output which is connected to the clock input of the distribution calculator, zeroing and control outputs of the control unit are connected respectively to zeroing m and the control inputs of the parameter calculation unit, the information input of which is connected to the output of the input amplifier, the first and second information outputs of the parameter calculation unit are connected respectively to the first and second information inputs of the arithmetic mean value calculation unit, the first information output of which is connected to the first information input of the distribution calculator and with the input of the distribution type determination unit, the first, second, and third modification outputs of which are connected respectively To the first, second, and third modification inputs of the distribution calculator, the second information input of which is connected to the second information output of the arithmetic mean value calculation unit, the output of the distribution calculator is the output of the device, and an intensity analysis block is additionally introduced. The input of the intensity analysis unit is connected to the second information output of the parameter calculation unit, the first and second parametric outputs of the intensity analysis unit are connected respectively to the first and second parametric inputs of the distribution calculator, the control output of the intensity analysis unit is connected to the control input of the arithmetic mean value calculation unit.

 The unit for calculating arithmetic mean values consists of a counter-divider of the duration values, a counter-divider of the intensity values and the element BAN. The input of the counter-divider of the duration values is the first information input of the block for calculating arithmetic mean values, the output of the counter-divider of the duration values is the first information output of the block. The input of the counter-divider of the intensity values is the second information input of the block for calculating arithmetic mean values, the output of the counter-divider of the intensity values is connected to the enable input of the BAN element. The inhibitory input of the element FORBID is the control input of the block for calculating arithmetic mean values, the output of the element FORBID is the second information output of the block.

 The distribution calculator consists of an arithmetic logic device and the element I. The first and second information inputs of the arithmetic logic device are the first and second information inputs of the distribution calculator, respectively. The first, second and third modification inputs of the arithmetic logic device are respectively the first, second and third modification inputs of the distribution calculator. The first and second parametric inputs of the arithmetic logic device are respectively the first and second parametric inputs of the distribution calculator. The first input of the AND element is the clock input of the distribution calculator, the output of the And element is connected to the clock input of the arithmetic-logic device. The second input of the AND element is connected to the first information input of the distribution calculator, the output of the arithmetic logic device is the output of the distribution calculator.

 The intensity analysis block consists of a comparison circuit, random access memory, primary element And and secondary element I. The information inputs of the comparison circuit and secondary element And are connected to the input of random access memory, which is the input of the intensity analysis block, the auxiliary output of random access memory is connected to the auxiliary input comparison circuit, the output of which is the control output of the intensity analysis unit and is connected in parallel with the signal inputs and primary and secondary elements AND, the outputs of which are respectively the first and second parametric outputs of the intensity analysis unit, the information output of the random access memory is connected to the information input of the primary element I.

 The principle of creating the proposed device is based on the possibility of estimating the distribution law using average values of the parameters of various varieties of heterogeneous (homogeneous and heterogeneous) MPS flows, relying either on algorithms for approximating real statistics of incoming flows and reducing them directly to three known modifications [1], or on algorithms superpositions of incoming flows [1, 2, 3] - in cases where there is a source of heterogeneous (mixed) information that gives out as distinct independent and single ICP, and packs of ICP, the lengths of which are distributed according to a geometric law.

2. Сложный поток МПС (m_п < m_с и ζ < 1) с распределением:

3. Прореженный поток МПС (m_п > m_с и ζ > 1) с распределением:

Кроме того, если при аппроксимации реальной статистики входящих потоков ИСП не удается свести их непосредственно к трем рассмотренным выше модификациям потоков сообщений, то используют суперпозицию входящих потоков [1-3]. Например, если в составе ЦСИО имеется оконечный терминал - источник информации, который передает смешанные МПС - как явно выраженные независимые и одиночные ИСП, так и пачки ИСП, длины которых распределены по геометрическому закону, то для описания такого входящего потока ИСП следует использовать суперпозицию потоков, описываемых выражениями (1) и (2) [1].There are three main varieties of MPS flows of ISSC users, the distributions of which are described in [1]:
1. A simple stream of MPS (the number of elements in the information part of message packets is equal to the number of elements contained in the information part of MPS, that is, m _p = m _s and ζ = m _p / m _s = 1), the distribution of the number of packets of which is determined by the expression

2. The complex flow of MPS (m _p <m _s and ζ <1) with the distribution:

3. Thinned stream of MPS (m _p > m _s and ζ> 1) with the distribution:

In addition, if, when approximating the actual statistics of incoming ICP flows, it is not possible to reduce them directly to the three modifications of message flows considered above, then a superposition of incoming flows is used [1-3]. For example, if an ISDN has a terminal terminal - a source of information that transmits mixed MPS - both distinct independent and single ICPs and ICP packets whose lengths are distributed according to a geometric law, then a superposition of flows should be used to describe such an incoming ICP stream, described by expressions (1) and (2) [1].

Анализ приведенных выражений позволяет сделать вывод о том, что оценку распределения разнородного (однородного и неоднородного) потока МПС можно получить на основе определения параметров потока λ и ζ. Использование в этих целях устройства-прототипа (см. патент РФ N 2094844, G 06 F 17/18, 1997, бюл. 30) является нецелесообразным в силу его неспособности производить оценку распределения неоднородного (смешанного) потока МПС, доля которого в суммарном потоке ЦСИО очень велика [1]. Для определения типа распределения потока сообщений, циркулирующего в реальной ЦСИО, недостаточно реализовать расчет одного из трех аналитических выражений (1-3) по усредненным за интервал наблюдения параметрам λ и ζ, необходима верификация решения об однородности потока МПС и принятие решения на параметрическую оценку закона распределения в соответствии с выражением (4) в случае признания потока неоднородным (смешанным).Then it can be shown [3] that the probability P (u _p = k) is a convolution of the corresponding probabilities and is equal to

An analysis of the above expressions allows us to conclude that an estimate of the distribution of a heterogeneous (homogeneous and heterogeneous) MPS stream can be obtained based on the determination of the flow parameters λ and ζ. The use of a prototype device for this purpose (see RF patent N 2094844, G 06 F 17/18, 1997, bull. 30) is impractical due to its inability to assess the distribution of an inhomogeneous (mixed) MPS stream, the share of which in the total ISSC stream very large [1]. To determine the type of distribution of the message flow circulating in a real ISDS, it is not enough to calculate one of the three analytical expressions (1-3) using the parameters λ and ζ averaged over the observation interval, it is necessary to verify the decision on the uniformity of the MPS stream and make a decision on a parametric estimate of the distribution law in accordance with expression (4) if the flow is recognized to be heterogeneous (mixed).

 An analysis of expressions (1-4) allows us to conclude that it is possible to technically realize the estimated values of the parameters of the law of distribution of heterogeneous (homogeneous and heterogeneous) flows of MPS circulating in the center

 The construction of a device based on the proposed principle of operation allows one to gain an advantage over the prototype by providing the ability to evaluate the values of the parameters of the distribution law of both homogeneous and inhomogeneous (mixed) flows of MPS users of a centralized communication center. This significantly expands the device’s functionality, making it possible to evaluate the parameters of message flows circulating in real digital networks, taking into account the presence of both regular information sources and mixed-type sources that issue messages irregularly — single ICPs or ICP packets with lengths distributed along geometric the law [1].

The claimed device is illustrated by drawings, on which are presented:
in FIG. 1 is a block diagram of a device for parametric estimation of the distribution law of message flows;
in FIG. 2 is a block diagram of a block for calculating arithmetic mean values;
in FIG. 3 is a block diagram of a distribution calculator;
in FIG. 4 is a block diagram of an intensity analysis unit;
in FIG. 5 is a block diagram of a parameter calculation unit;
in FIG. 6 is a block diagram of a distribution type determination unit;
in FIG. 7 is a structural diagram of a control unit.

 The device for parametric estimation of the law of distribution of message flows depicted in FIG. 1, consists of an input amplifier 1, the input of which is supplied with a binary pulse sequence, a parameter calculation unit 2, an arithmetic mean calculation unit 3, a distribution type determination unit 4, a distribution calculator 5, a control unit 6, and an intensity analysis unit 7. Clock output 61 control unit 6 is connected to the clock input 56 of the distribution calculator 5, resetting 62 and controlling 63 the outputs of control unit 6 are connected respectively to resetting 22 and control 23 inputs of the unit for calculating parameters 2, information input 21 of which is connected to the output of input amplifier 1, the first 24 and second 25 information outputs of the unit for calculating parameters 2 are connected respectively to the first 31 and second 32 information inputs of the unit for calculating arithmetic mean values 3, the first information output 33 of which is connected to the first information input 51 distribution calculator 5 and with the input of the distribution type determination unit 4, the first 41, the second 42 and the third 43 whose modification outputs are connected respectively to the first 53, second 54 and tr To the network 55, the modification inputs of the distribution calculator 5, the second information input 52 of which is connected to the second information output 34 of the arithmetic mean value calculation unit 3, the output of the distribution calculator 5 is the output of the device. The input of the intensity analysis unit 7 is connected to the second information output 25 of the parameter calculation unit 2, the first 73 and second 74 parametric outputs of the intensity analysis unit 7 are connected respectively to the first 57 and second 58 parametric inputs of the distribution calculator 5, the control output 72 of the intensity analysis unit 7 is connected to control input 35 of the calculation unit of arithmetic mean values 3.

и состоит из счетчика-делителя значений длительности 3.01, счетчика-делителя значений интенсивности 3.02 и элемента ЗАПРЕТ 3.03. Вход счетчика-делителя значений длительности 3.01 является первым информационным входом 31 блока вычисления средних арифметических значений 3, выход счетчика-делителя значений длительности 3.01 является первым информационным выходом 33 блока 3. Вход счетчика-делителя значений интенсивности 3.02 является вторым информационным входом 32 блока вычисления средних арифметических значений 3, выход счетчика-делителя значений интенсивности 3.02 подключен к разрешающему входу элемента ЗАПРЕТ 3.03. Запрещающий вход элемента ЗАПРЕТ 3.03 является управляющим входом 35 блока вычисления средних арифметических значений 3, выход элемента ЗАПРЕТ 3.03 является вторым информационным выходом 34 блока 3. Счетчик-делитель значений длительности 3.01 и счетчик-делитель значений интенсивности 3.02 могут быть технически реализованы в виде счетчика-делителя с переменным коэффициентом деления, работающего как суммирующий двоичный, как показано в [4, стр. 181-182, рис. 5.47]. Элемент ЗАПРЕТ 3.03 может быть реализован в соответствии с описанным в [4, стр. 24, рис. 1.5 (д,е)].The unit for calculating arithmetic mean values 3 (Fig. 2) is designed to obtain numerical values averaged over the observation interval of the flow parameters

and consists of a counter-divider of values of duration 3.01, a counter-divider of values of intensity 3.02 and the element BAN 3.03. The input of the counter-divider of values of duration 3.01 is the first information input 31 of the block for calculating arithmetic mean values 3, the output of the counter-divider of values of duration 3.01 is the first information output of block 33 of 3. The input of the counter-divider of intensity values 3.02 is the second information input 32 of the block for calculating arithmetic mean 3, the output of the counter-divider of intensity values 3.02 is connected to the enable input of the element BAN 3.03. The inhibitory input of the element PROHIBITION 3.03 is the control input 35 of the block for calculating arithmetic mean values 3, the output of the element PROHIBITION 3.03 is the second information output 34 of the block 3. The counter-divider of the values of duration 3.01 and the counter-divider of the values of intensity 3.02 can be technically implemented as a counter-divider with a variable division coefficient, operating as a summing binary, as shown in [4, p. 181-182, Fig. 5.47]. The element BAN 3.03 can be implemented as described in [4, p. 24, Fig. 1.5 (d, f)].

 Distribution calculator 5 shown in FIG. 3, is intended to obtain estimated distribution values in accordance with expressions (1-4) and consists of an arithmetic-logic device 5.01 and the element And 5.02. The first 501 and second 502 information inputs of the arithmetic logic device 5.01 are respectively the first 51 and second 52 information inputs of the distribution calculator 5. The first 503, second 504, and third 505 modification inputs of the arithmetic logic device 5.01 are respectively the first 53, second 54, and third 55 the modification inputs of the distribution calculator 5. The first 507 and second 508 parametric inputs of the arithmetic-logic device 5.01 are respectively the first 57 and second 58 parameter inputs of the calculator distribution 5. The first input 510 of the AND element 5.02 is the clock input 56 of the distribution calculator 5, the output of the And 5.02 element is connected to the clock input 506 of the arithmetic logic device 5.02. The second input 511 of the AND element 5.02 is connected to the first information input 51 of the distribution calculator 5, the output 509 of the arithmetic logic device 5.01 is the output 59 of the distribution calculator 5. The arithmetic logic device 5.01 can be technically implemented as a conventional arithmetic logic device (ALU), described in [5, p. 158-170]. Element And 5.02 can be implemented as described in [4, p. 13-14, Fig. 1.2].

The intensity analysis unit 7 (Fig. 4) is intended for the current estimation and comparison of the previous (λ ₁ ) and subsequent (λ ₂ ) values of the samples of the input stream parameter λ and consists of a comparison circuit 7.01, random access memory 7.02, primary element And 7.03 and secondary element AND 7.04. The information inputs 701 and 706 of the comparison circuit 7.01 and the secondary element And 7.04 are respectively connected to the input of random access memory 7.02, which is the input 71 of the intensity analysis unit 7, the auxiliary output 707 of the random access memory 7.02 is connected to the auxiliary input 702 of the comparison circuit 7.01, the output of which is the control output 72 of the intensity analysis unit 7 and is connected in parallel with the signal inputs 703 and 705 of the primary 7.03 and secondary 7.04 elements And, respectively, the outputs of which are respectively GOVERNMENTAL first 73 and second 74 outputs block parametric analysis intensity 7, data output 708, a random access memory 7.02 is connected to the data input 704 of the primary element and 7.03. The comparison scheme 7.01 can be technically implemented as a comparison node (digital comparator), as shown in [4, p. 149-152, Fig. 5.19]. Random Access Memory (RAM) 7.02 is implemented as a storage register in accordance with the description presented in [4, p. 156-158, Fig. 5.27]. Primary 7.03 and secondary 7.04 And elements are implemented as standard And elements, as shown in [4, p. 13-14, Fig. 1.2].

 The input amplifier 1, which is part of the general block diagram, is designed to carry out the amplification procedure, normalizing the amplitude and duration of the input stream — a binary pulse sequence. Input amplifier 1 can be technically implemented as a Schmitt trigger, as shown in [4, pp. 117–191, Fig. 4.12 (a)].

 The unit for calculating parameters 2, which is part of the general block diagram, is designed to determine the current values of the parameters λ and ζ. Its circuit is known, described, for example, in RF patent N 2094844 and is presented in FIG. 5 of this description. The parameter computing unit 2 comprises a packet header decoder 2.01, pause detector 2.02, an information length counter of the MMS IP 2.03, a message counter 2.04, a calculator of the ratio of information lengths of packets and messages 2.05. In this case, the input 21 of the packet header decoder, which is the input of block 2, is connected in parallel to the first input of the information length counter of the MMS messages 2.03, and the pause detector 2.02 input, the output of the packet header decoder 2.01 is connected to the second input of the information length counter of the MMS messages 2.03. The output of the pause detector 2.02 is connected to the third input of the information length counter of the MMS messages 2.03 and to the first input of the message counter 2.04, the output of the information length counter of the messages MMS 2.03 is connected to the first input of the calculator of the ratio of information lengths of packets and messages 2.05, the second control input of which 23, like the second nulling input of the message counter 22 is connected respectively to the control 63 and nullifying 62 outputs of the control unit 6, and the outputs of which are the first 24 and second 25 information outputs of the subtraction unit Merging parameters 2.

с единичным порогом и принятия решения о принадлежности однородного входного потока к одной из трех модификаций, описываемых выражениями (1-3). Схема блока определения типа распределения 4 известна, описана, например, в патенте РФ N 2094844 и представлена на фиг. 6 данного описания. Блок определения типа распределения 4 содержит цифроаналоговый преобразователь (ЦАП) 4.01, два компаратора 4.02, 4.03, генератор порогового напряжения 4.04, элемент ИЛИ-НЕ 4.05. При этом вход цифроаналогового преобразователя 4.01 соединен с первым информационным выходом 33 блока вычисления средних арифметических значений 3, выход цифроаналогового преобразователя 4.01 соединен с первыми входами компараторов 4.02 и 4.03, вторые входы которых подключены к выходу генератора порогового напряжения 4.04, выходы компараторов являются первым 41 и вторым 42 модификационными выходами блока 4, соединены с первым и вторым входами элемента ИЛИ-НЕ 4.05 и с первым 53 и вторым 54 модификационными входами вычислителя распределения 5, выход элемента ИЛИ-НЕ 4.05 является третьим модификационным выходом 43 блока 4 и подключен к третьему модификационному входу 55 вычислителя распределения 5.The block for determining the type of distribution 4, which is part of the general block diagram, is intended for the implementation of the procedure for comparing the values of the duration parameter

with a single threshold and deciding whether the homogeneous input stream belongs to one of the three modifications described by expressions (1-3). The layout of the distribution type determination unit 4 is known, described, for example, in RF patent N 2094844 and is presented in FIG. 6 of this description. The distribution type determination unit 4 contains a digital-to-analog converter (DAC) 4.01, two comparators 4.02, 4.03, a threshold voltage generator 4.04, an OR-NOT 4.05 element. The input of the digital-to-analog converter 4.01 is connected to the first information output 33 of the arithmetic mean value calculation unit 3, the output of the digital-to-analog converter 4.01 is connected to the first inputs of the comparators 4.02 and 4.03, the second inputs of which are connected to the output of the threshold voltage generator 4.04, the outputs of the comparators are the first 41 and second 42 modification outputs of block 4 are connected to the first and second inputs of the OR-NOT 4.05 element and to the first 53 and second 54 modification inputs of the distribution calculator 5, the output is elem coagulant NOR 4.05 Modification is the third output 43 of block 4 and connected to the third input 55 of the modification calculator 5 distribution.

The control unit 6, which is part of the general block diagram, is designed to adjust the observation interval (t _nab ), packet length (m _p ) and the number of packets (k). Its circuit is known, described, for example, in RF patent N 2094844 and is presented in FIG. 7 of this description. The control unit 6 contains a clock generator 6.01 and three dividers with a variable division ratio (DPKD) 6.02 - 6.04. The output of the clock 6.01 is connected in parallel to the inputs of all three dividers with a variable division ratio, the output of the first of which (6.02) is the clock output 61 of block 6 and connected to the clock input 56 of the distribution calculator 5, and the outputs 62, 63 of two other dividers with a variable division factor of 6.04 and 6.03 are respectively the zeroing (62) and controlling (63) outputs of block 6 and are connected to zeroing 22 and 23 controlling inputs of the block for calculating parameters 2.

A device for parametric estimation of the law of distribution of message flows works as follows. The studied input stream of the MPS of the users of the center for digital signal analysis in the form of a binary pulse sequence, amplified and normalized in amplitude and duration by the input amplifier 1, is fed to input 21 of the parameter calculation block 2, in which the current values of the parameters λ and ζ are determined. The parameter calculating unit may be implemented in accordance with the circuit proposed in FIG. 5. The calculation in block 2 of the current values of the parameters λ and ζ is as follows. The decoder 2.01 analyzes the pulse sequence received at the input of the parameter calculation unit 2 and, when it detects a sign of the beginning of the informational part of the packet, starts the counter 2.03, the moments of completion are determined by the moments when the decoder detects the end of the informational part of the packet. The moments of arrival of values of the information length of the message m _c in the calculator of the relations of information lengths 2.05 and zeroing of the counter 2.03 are determined by the moments of the appearance of pulses at the output of the pause detector 2.02, fixing the end of the message. In the calculator of the ratio of information lengths of packets and messages 2.05, the values ζ = m _p / m _{s are} determined for a fixed length of packets received in the ISSC and installed by the control unit 6, by supplying to the control input 23 of the block 2.05 pulses, the number of which corresponds to the value of m _c . The intensity value λ is determined by the counter 2.04 by pulses from the output of the pause detector 2.02 for the time interval determined by the control unit 6, by supplying pulses with a frequency f _n to the zeroing input 22 of the counter 2.04.

 The values ζ and λ in the parallel code, respectively, come from the information outputs 24 and 25 of the parameter calculation block 2 to the information inputs 31 and 32 of the arithmetic mean value calculation unit 3. The arithmetic mean value calculation unit 3 can be implemented according to the circuit shown in FIG. 2.

происходит следующим образом. Значения параметра ζ в виде бинарной последовательности поступают на первый информационный вход 31 блока 3, а затем на вход счетчика-делителя значений длительности 3.01, производящего арифметическую операцию суммирования последовательно поступающих значений ζ и деление полученной суммы на количество отсчетов. На выходе счетчика-делителя значений длительности 3.01 и на первом информационном выходе 33 блока вычисления средних арифметических значений 3 в двоичном параллельном коде получаем значение параметра

усредненного за интервал наблюдения. Значения параметра λ в виде бинарной последовательности поступают на второй информационный вход 32 блока 3, а затем на вход счетчика-делителя значений интенсивности 3.02, производящего арифметическую операцию суммирования последовательно поступающих значений λ и деление полученной суммы на количество отсчетов. На выходе счетчика-делителя значений интенсивности 3.02 и на разрешающем входе элемента ЗАПРЕТ 3.03 в двоичном параллельном коде имеем значение параметра

усредненного за интервал наблюдения. На второй информационный выход 34 блока 3 с выхода элемента ЗАПРЕТ 3.03 значение

попадает лишь в том случае, если в данный момент на управляющий вход 35 блока 3 и на запрещающий вход элемента ЗАПРЕТ 3.03 не подан в двоичном параллельном коде сигнал с управляющего выхода 72 блока анализа интенсивности 7. В противном случае на второй информационный выход 34 блока 3 с выхода элемента ЗАПРЕТ 3.03 значение параметра

не подается. Интервал наблюдения для расчета параметров

устанавливается блоком управления 6 в зависимости от требуемой точности.In the case when there is a homogeneous (unmixed) MPS stream of users of the ISDN, when the sources issue messages regularly, calculation of numerical values averaged over the observation interval of the flow parameters

happens as follows. The values of the parameter ζ in the form of a binary sequence are fed to the first information input 31 of block 3, and then to the input of the counter-divider of the values of duration 3.01, which performs the arithmetic operation of summing the successively arriving values of ζ and dividing the sum obtained by the number of samples. At the output of the counter-divider of values of duration 3.01 and at the first information output 33 of the block for calculating arithmetic mean values 3 in binary parallel code, we obtain the parameter value

averaged over the observation interval. The values of the parameter λ in the form of a binary sequence are fed to the second information input 32 of block 3, and then to the input of the counter-divider of the intensity values 3.02, which performs the arithmetic operation of summing the successively arriving values of λ and dividing the resulting sum by the number of samples. At the output of the counter-divider of intensity values 3.02 and at the enable input of the element BAN 3.03 in binary parallel code, we have the value of the parameter

averaged over the observation interval. To the second information output 34 of block 3 from the output of the element BAN 3.03 value

gets only if at the moment the signal from the control output 72 of the intensity analysis block 7 is not sent in binary parallel code to the control input 35 of block 3 and to the inhibitory input of the element BAN 3.03; otherwise, the second information output 34 of block 3 s output element BAN 3.03 parameter value

not served. Observation interval for calculating parameters

set by the control unit 6 depending on the required accuracy.

The control unit 6 may be implemented according to the circuit proposed in FIG. 7. The formation of the control pulse sequences is carried out by installing on the elements of the group of dividers with a variable division factor (DLC) the corresponding division factors of the pulse sequence coming from the output of the generator 6.01. By setting the coefficient of element 6.03, the value of t _nab = 1 / f _nab is determined, by setting the coefficient of element 6.04, the packet length currently accepted in the ISDN is determined (m _p ), by setting the coefficient of element 6.02, the number of packets necessary for calculating expressions (1-4) is determined ( k).

соответственно, значение

c первого информационного выхода 33 блока 3 подается на вход блока определения типа распределения 4, в котором происходит его сравнение с единичным порогом. Блок определения типа распределения 4 может быть реализован по схеме, предложенной на фиг. 6. Определение типа распределения потока МПС осуществляется следующим образом. Значения

поступающие с выхода блока 3 в двоичном параллельном коде, в ЦАП 4.01 преобразуются в аналоговое напряжение, которое на компараторах 4.02, 4.03 сравнивается с пороговым напряжением, вырабатываемым генератором порогового напряжения 4.04. Значение порогового напряжения соответствует единичному значению

На выходе 42 компаратора 4.02 появляется сигнал логической единицы в случае превышения значения

единичного значения и поступает на второй модификационный вход 54 вычислителя распределения 5, в обратном случае появление логической единицы происходит на выходе 41 компаратора 4.03 и поступает на первый модификационный вход 53 вычислителя распределения 5. При наличии логических нулей на выходах компараторов 4.02 и 4.03 принимается решение о том, что

об этом свидетельствует наличие логической единицы на выходе 43 элемента ИЛИ-НЕ 4.05 и поступление этой логической единицы на третий модификационный вход 55 блока 5. Таким образом, по результатам сравнения, путем подачи управляющего импульса на один из трех модификационных входов 53-55 вычислителя распределения 5, принимается решение о вычислении одного из аналитических выражений (1-3) по значениям параметров

, поступающих с первого 33 и второго 34 информационных выходов блока 3 на первый 51 и второй 52 информационные входы вычислителя распределения 5. Вычисления могут быть проведены для различных значений количества пакетов (k), выбор значений осуществляется блоком управления 6 путем подачи на тактовый вход 56 блока 5 и на первый вход 510 элемента И 5.02 импульсов, количество которых соответствует заданному значению количества пакетов. Поступление на второй вход 511 элемента И 5.02 импульсов с первого информационного входа 51 блока 5 обеспечивает появление на выходе элемента И 5.02 управляющего сигнала, количество импульсов которого соответствует заданному значению количества пакетов. Данный сигнал, поступая на тактовый вход 506 арифметико-логического устройства 5.01, инициирует начало процедуры вычисления. Вычисленные значения распределения однородного потока МПС с выхода 59 вычислителя распределения 5 подаются в двоичном параллельном коде на устройство регистрации.When at the first 33 and at the second 34 information outputs of block 3 we have simultaneously the values of the parameters

accordingly, the value

c of the first information output 33 of block 3 is fed to the input of the block determining the type of distribution 4, in which it is compared with a unit threshold. The distribution type determination unit 4 may be implemented according to the circuit proposed in FIG. 6. The determination of the type of MPS flow distribution is as follows. Values

coming from the output of block 3 in binary parallel code, the DAC 4.01 is converted to an analog voltage, which on comparators 4.02, 4.03 is compared with the threshold voltage generated by the threshold voltage generator 4.04. The threshold voltage value corresponds to a unit value

At the output 42 of the comparator 4.02, a signal of a logical unit appears in case of exceeding the value

unit value and goes to the second modification input 54 of the distribution calculator 5, otherwise the logical unit appears at the output 41 of the comparator 4.03 and goes to the first modification input 53 of the distribution calculator 5. If there are logical zeros at the outputs of the comparators 4.02 and 4.03, the decision is made , what

this is evidenced by the presence of a logical unit at the output of the 43 element OR NOT 4.05 and the arrival of this logical unit to the third modification input 55 of block 5. Thus, according to the comparison results, by supplying a control pulse to one of the three modification inputs 53-55 of the distribution calculator 5 , a decision is made to calculate one of the analytical expressions (1-3) from the parameter values

coming from the first 33 and second 34 information outputs of block 3 to the first 51 and second 52 information inputs of the distribution calculator 5. Calculations can be performed for various values of the number of packets (k), the choice of values is carried out by the control unit 6 by applying to the clock input 56 of the block 5 and to the first input 510 of the AND element 5.02 pulses, the number of which corresponds to a given value of the number of packets. The arrival at the second input 511 of the element And 5.02 pulses from the first information input 51 of block 5 provides the appearance of a control signal at the output of the element And 5.02, the number of pulses of which corresponds to a given value of the number of packets. This signal, arriving at the clock input 506 of the arithmetic-logic device 5.01, initiates the start of the calculation procedure. The calculated distribution values of the uniform MPS stream from the output 59 of the distribution calculator 5 are supplied in binary parallel code to the registration device.

происходит так, как описано выше, а расчет численных значений параметра λ, характеризующего интенсивность потока, происходит следующим образом. Значения параметра λ в виде бинарной последовательности поступают на второй информационный вход 32 блока 3 для вычисления усредненного за интервал наблюдения параметра потока

и на вход 71 блока анализа интенсивности 7. Значения параметра λ поступают параллельно на информационный вход 701 схемы сравнения 7.01 блока 7, на вход ОЗУ 7.02 блока 7 и на информационный вход 706 вторичного элемента И 7.04 блока 7. В ОЗУ 7.02 хранится значение параметра λ на предыдущем шаге - значение λ₁. С вспомогательного выхода 707 ОЗУ 7.02 значение λ₁ поступает на вспомогательный вход 702 схемы сравнения 7.01, которая сравнивает значение предыдущего отсчета параметра (λ₁) со значением последующего отсчета (λ₂) - значением, поступившим на информационный вход 701 схемы сравнения 7.01. Сравнение производится по двум критериям: λ₁ ≠ λ₂ и λ₁ = λ₂. Если значения отсчетов равны (λ₁ = λ₂), это подтверждает, что на входе устройства мы имеем однородный (несмешанный) поток МПС, а значит, схема сравнения 7.01 не выдает сигнал на управляющий выход 72 блока 7 и на сигнальные входы элементов И 7.03 и 7.04. Это значит, что на управляющий вход 35 блока 3 и на запрещающий вход элемента ЗАПРЕТ 3.03 блока 3 с выхода 72 блока 7 сигнал не поступает, следовательно, на выходе элемента ЗАПРЕТ 3.03 и на втором информационном выходе 34 блока 3 в двоичном параллельном коде имеем значение параметрам

и дальнейший расчет параметров закона распределения потоков сообщений происходит так, как описано выше.In the case when there is an inhomogeneous (mixed) MPS stream of users of the ISDN, when mixed-type sources issue messages irregularly - by single ICPs or packets of ICPs with lengths distributed according to a geometric law, calculation of numerical values of the flow parameter averaged over the observation interval

occurs as described above, and the calculation of the numerical values of the parameter λ characterizing the flow intensity occurs as follows. The values of the parameter λ in the form of a binary sequence are fed to the second information input 32 of block 3 for calculating the flow parameter averaged over the observation interval

and to the input 71 of the intensity analysis block 7. The values of the parameter λ are sent in parallel to the information input 701 of the comparison circuit 7.01 of block 7, to the input of RAM 7.02 of block 7 and to the information input 706 of the secondary element And 7.04 of block 7. In RAM 7.02, the value of parameter λ is stored on the previous step is the value of λ ₁ . From the auxiliary output 707 of RAM 7.02, the value λ _{1 is} supplied to the auxiliary input 702 of the comparison circuit 7.01, which compares the value of the previous reference parameter (λ ₁ ) with the value of the subsequent reference (λ ₂ ) - the value received at the information input 701 of the comparison circuit 7.01. The comparison is made according to two criteria: λ ₁ ≠ λ ₂ and λ ₁ = λ ₂ . If the values of the samples are equal (λ ₁ = λ ₂ ), this confirms that at the input of the device we have a homogeneous (unmixed) MPS stream, which means that the comparison circuit 7.01 does not give a signal to the control output 72 of block 7 and to the signal inputs of elements And 7.03 and 7.04. This means that the signal is not received at the control input 35 of block 3 and at the inhibitory input of the element BAN 3.03 of block 3 from the output 72 of block 7, therefore, at the output of the element BAN 3.03 and at the second information output 34 of block 3 in binary parallel code, we have the parameter values

and further calculation of the parameters of the law of distribution of message flows occurs as described above.

на второй информационный вход 52 блока 5. С информационного выхода 708 ОЗУ 7.02 значение параметра λ₁ поступает на информационный вход 704 первичного элемента И 7.03, а в ОЗУ записывается значение нового параметра. На информационном входе 706 вторичного элемента И 7.04 имеем значение λ₂. Сигнал с выхода схемы сравнения 7.01, поступая на сигнальные входы 703 и 705 первичного и вторичного элементов И (7.03 и 7.04) соответственно, открывает эти устройства, позволяя получать на их выходах, а значит, и на первом 73 и втором 74 параметрических выходах блока 7 значения параметра λ₁ и λ₂ соответственно. Значения параметра λ₁ и λ₂ поступают на первый 57 и второй 58 параметрические входы вычислителя распределения 5, а затем на первый 507 и второй 508 параметрические входы арифметико-логического устройства 5.01, которое вычисляет значения распределения в соответствии с аналитическим выражением (4), причем наличие управляющего импульса на любом из трех модификационных входов 53-55 вычислителя распределения 5 в этом случае роли не играет. Вычисленные значения распределения неоднородного (смешанного) потока МПС с выхода 59 вычислителя распределения 5 подаются в двоичном параллельном коде на устройство регистрации.If the values of the samples are not equal (λ ₁ ≠ λ ₂ ), this confirms that at the input of the device we have a heterogeneous (mixed) MPS stream, which means that the comparison circuit 7.01 gives a signal to the control output 72 of block 7 and to the signal inputs of elements And 7.03 and 7.04. The signal from the control output 72 of block 7 is fed to the control input 35 of block 3 and to the inhibitory input of the element FORBID 3.03, locking its output and not allowing to give out values

to the second information input 52 of block 5. From the information output 708 of RAM 7.02, the value of the parameter λ ₁ goes to the information input 704 of the primary element AND 7.03, and the value of the new parameter is written to RAM. At the information input 706 of the secondary element And 7.04 we have the value of λ ₂ . The signal from the output of the comparison circuit 7.01, arriving at the signal inputs 703 and 705 of the primary and secondary elements And (7.03 and 7.04), respectively, opens these devices, allowing them to receive at their outputs, and therefore, at the first 73 and second 74 parametric outputs of block 7 the values of the parameter λ ₁ and λ _2, respectively. The values of the parameter λ ₁ and λ ₂ are fed to the first 57 and second 58 parametric inputs of the distribution calculator 5, and then to the first 507 and second 508 parametric inputs of the arithmetic-logic device 5.01, which calculates the distribution values in accordance with the analytical expression (4), and the presence of a control pulse at any of the three modification inputs 53-55 of the distribution calculator 5 does not play a role in this case. The calculated distribution values of the heterogeneous (mixed) MPS stream from the output 59 of the distribution calculator 5 are supplied in binary parallel code to the registration device.

 As a result, at the output of block 5, we have the distribution values of either a homogeneous or inhomogeneous (mixed) MPS stream recorded in binary code, depending on the characteristics of the ISDN traffic.

 Thus, the analysis of the principle of operation of the inventive device for parametric estimation of the law of distribution of message flows shows the evidence of the fact that, along with the saved capabilities of estimating the distribution parameters of homogeneous (unmixed) MPS flows, the device is able to estimate the distribution parameters of inhomogeneous (mixed) MPS flows (share which are very large in the total flow of the center for centralized interconnection) - flows that periodically change their intensity during the operation of the network. This device allows you to obtain in the dynamics the estimated values of the parameters of the law of distribution of heterogeneous (homogeneous and heterogeneous) streams of MPS circulating in the center, which significantly expands the scope of the device, expands the functionality of the equipment, where the claimed device for parametric estimation of the law of distribution of message flows will be used.

Sources of information
1. Sovetov B.Ya., Yakovlev S.A. Building Integrated Services Networks. - L .: Mechanical Engineering, 1990.p. 113 - 116.

 2. Ovcharov L.A. Applied problems of queuing theory. - M.: Mechanical Engineering, 1969. - 324 p.

 3. Sovetov B.Ya., Rukhman E.L., Yakovlev S.A. Systems for transmitting information from terminals to digital computers. - L .: ed. Leningrad University, 1978. -240 s.

 4. Gusev VV, Lebedev O.N., Sidorov A.M. Fundamentals of pulsed and digital technology. - SPb .: SPVVIUS, 1996 .-- 247 p.

 5. Drozdov EA, Komarnitsky VA, Pyatibratov AP Electronic computers of the Unified system. - M.: Mechanical Engineering, 1981.

Claims (4)

 1. A device for parametric estimation of the law of distribution of message flows, comprising an input amplifier, the input of which is a binary pulse sequence, blocks for calculating parameters, calculating arithmetic mean values, determining the type of distribution, a distribution calculator, and a control unit whose clock output is connected to the clock input of the calculator distribution, zeroing and control outputs of the control unit are connected respectively to zeroing and control inputs of the unit for calculating steam meters, the information input of which is connected to the output of the input amplifier, the first and second information outputs of the parameter calculation unit are connected respectively to the first and second information inputs of the arithmetic mean value calculation unit, the first information output of which is connected to the first information input of the distribution calculator and to the input of the type determination unit distribution, the first, second and third modification outputs of which are connected respectively to the first, second and third modifications to the input inputs of the distribution calculator, the second information input of which is connected to the second information output of the arithmetic mean value calculation unit, the output of the distribution calculator is the output of the device, characterized in that an intensity analysis unit is added, the input of which is connected to the second information output of the parameter calculation unit, the first and the second parametric outputs of the intensity analysis unit are connected respectively to the first and second parametric inputs of the calculator I distribution, the control output of the intensity analysis unit is connected to the control input of the calculation of arithmetic mean values.  2. A device for parametric estimation of the law of distribution of message flows according to claim 1, characterized in that the arithmetic mean calculation unit consists of a counter-divider of duration values, a counter-divider of intensity values and a BAN element, and the input of the counter-divider of duration values is the first the information input of the block for calculating arithmetic mean values, the output of the counter-divider of the duration values is the first information output of the block, the input of the counter-divider of values and intensity is the second information input of the arithmetic mean value calculation unit, the output of the intensity divider is connected to the enable input of the FORBID element, the inhibitory input of the FORBID element is the control input of the arithmetic mean value calculation unit, the output of the FORBID element is the second information output of the block.  3. A device for parametric estimation of the law of distribution of message flows according to claim 1, characterized in that the distribution calculator consists of an arithmetic logic device and an And element, the first and second information inputs of the arithmetic logic device being the first and second information inputs of the distribution calculator, respectively , the first, second and third modification inputs of the arithmetic-logical device are respectively the first, second and third modification inputs of the calculator First, the second and second parametric inputs of the arithmetic logic device are respectively the first and second parametric inputs of the distribution calculator, the first input of the And element is the clock input of the distribution calculator, the output of the And element is connected to the clock input of the arithmetic-logical device, the second input of the And element is connected to the first information input of the distribution calculator, the output of the arithmetic-logical device is the output of the distribution calculator.  4. The device for parametric estimation of the law of distribution of message flows according to claim 1, characterized in that the intensity analysis unit consists of a comparison circuit, random access memory, primary element And and secondary element And, and the information inputs of the comparison circuit and secondary element And are connected to the input of random access memory, which is the input of the intensity analysis unit, the auxiliary output of the random access memory is connected to the auxiliary input of the comparison circuit, the output of which is the control output of the intensity analysis unit and is connected in parallel with the signal inputs of the primary and secondary elements And, the outputs of which are the first and second parametric outputs of the intensity analysis unit, the information output of the random access memory is connected to the information input of the primary element I.

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