RU2517327C1 - Method (versions) of monitoring and providing required subscriber quality of service in multi-service networks - Google Patents

Abstract

FIELD: radio engineering, communication.

SUBSTANCE: method involves controlling access of incoming various applications based on different requirements for quality of service when estimating reservation thresholds and the required minimum volume of a channel resource. The fraction of lost applications is reduced via adaptation to the fast changing operating communication environment on a communication network and a unified telecommunication network using prediction of intensity of the proposed traffic and capabilities of the unified telecommunication network.

EFFECT: reducing the required channel resource for servicing various applications with different quality of service requirements.

2 cl, 11 dwg

Description

The invention relates to communication technology and multiservice communication networks, can be used to automatically provide the required quality of service delivery, reduce the required channel resource for serving diverse requests with different requirements for the quality of service.

A multiservice network is a network built in accordance with the NGN concept to serve the traffic of various communication applications (speech, video, data) (Stepanov S.N. Fundamentals of teletraffic of multiservice networks. - M.: Eco-Trends, 2010. - 392 p. C .22).

Known methods implemented in devices that reduce the time to determine the emergency state of communication channels ("Device for assessing the status of channels in simplex communication systems": patent SU 1197124 A, 02.10.84; "Device for assessing the state and management of channels and technical means in simplex communication systems ": patent RU 2007878 C1, 02/12/94, as well as the method implemented in the device, which allows to reduce the time to determine the emergency state of communication channels and use the components of the backup or main path, using zovat backup path in peak hours "Device for evaluation of technical status of channels and ensure stability and communication in telecommunication systems": Patent RU 2385537 C1, 27.03.2010).

The disadvantage of these analogues is that a significant amount of the channel resource is used to serve subscribers, because they do not take into account the various requirements for the quality of service of different types of applications and the features of their service, as well as non-fulfillment of requirements for the quality of service due to changes in operational communication conditions on the communication network and the unified telecommunication network.

The closest in technical essence to the method - the prototype, is the method implemented in the device ("Device for assessing the technical condition and ensuring the stability of communication channels and means in telecommunication systems": patent RU 2385537 C1, 03/27/2010). The method implemented in this device consists of the following actions:

1. Carry out technical control of the state of the main and backup paths without disconnecting subscribers.

2. Measure the information load.

3. Generate one of three types of control signals.

4. Switch messages to the backup channel if the backup distributor is free and the main one is overloaded, or all messages to the primary channel if the load has decreased and there is no need to use the backup channel.

5. Block messages with the lowest category if the primary and backup distributors are overloaded.

The prototype method under consideration has the ability to assess the technical condition and ensure the stability of communication channels and means in telecommunication systems, use part of the backup or main path, use the backup path during peak hours and monitor the technical condition of the paths without disconnecting subscribers.

However, the prototype method has the following disadvantage:

- a significant amount of channel resource is required due to the fact that the service features of heterogeneous applications with different requirements for the quality of their service are not taken into account, applications with lower requirements for the channel resource can crowd out applications with higher requirements from service, and there is no possibility of adaptation to rapidly changing operational environment for communication on a communication network, to the changing intensity of the proposed traffic and to the changing capabilities of a unified telecommunication network.

The objective of the invention is to develop a method (options) for monitoring and ensuring the required quality of customer service in multiservice networks, which allows to reduce the necessary amount of channel resources by controlling the admission of incoming multi-type applications taking into account different requirements for the quality of their service when evaluating reservation thresholds and the required minimum amount of channel resource and also reduce the share of lost applications by adapting to the rapidly changing operational environment of network communications communications and a unified telecommunication network using forecasting the intensity of the proposed traffic and the capabilities of a unified telecommunication network.

The quality of service delivery is estimated by the probability of loss of applications (Stepanov S.N. Fundamentals of teletraffic of multiservice networks. - M .: Eco-Trends, 2010. - 392 p. S.81).

An application is a user’s request to allocate a channel resource in order to transmit the corresponding information message (Stepanov S.N. Basics of teletraffic of multiservice networks. - M .: Eco-Trends, 2010. - 392 p. S.24).

A multiservice communication network node is a collection of devices located in one place and united by a single control (Stepanov S.N. Fundamentals of teletraffic of multiservice networks. - M.: Eco-Trends, 2010. - 392 p. S.23).

The objective of the invention in the first embodiment is solved by the fact that the method (s) of monitoring and providing the required quality of customer service in multiservice networks, which consists in measuring the information load, generating one of three types of control signals, switching the request for the backup channel, if the backup distributor it is free, and the main one is overloaded, or all applications for the main channel, if the load has decreased and there is no need to use a backup channel, while applications with the lowest category are blocked, if the new and reserve distributors are overloaded; according to the invention, it is supplemented: they specify the number of application flows for allocation of a channel resource n, k = 1, 2, ..., n, the intensity of the proposed traffic of the k-th application flow, a _k , different requirements for the quality of service for applications of the k-th flow π _{k tr} , π _{k tr} - the required share of lost applications, the number of units of the line resource needed to serve one application of the k-th stream b _k , and the number of application flows for allocation of the channel resource n, k = 1, 2, ..., is recorded n, the intensity of the proposed traffic of the k-th stream of applications a _k , different requirements for the quality of service of applications π _ktr , the number of units of the line resource needed to service one application of the k-th stream b _k , then estimate the reservation thresholds q _k and the required minimum amount of channel resource V and remember the reservation thresholds q _k and the required minimum amount of channel resource V, then, on the basis of the estimated necessary minimum amount of channel resource, it is formed, the occupied channel resource r is measured, an application is received from the subscriber for the provision of the k-th service, the busy channel is compared a resource with reservation thresholds, and according to the comparison results, the transfer request is switched if the occupied channel resource is less than or equal to the reservation threshold for this type of application, or the service request is deleted if the occupied channel resource is greater than the reservation threshold for this type of application.

The objective of the invention in the second embodiment is solved by the fact that the method (options) for monitoring and ensuring the required quality of customer service in multiservice networks, which consists in monitoring the status of the main and backup paths without disconnecting subscribers, according to the invention is supplemented: the number of application flow for allocation is set channel resource n, k = 1, 2, ..., n, the intensity of the proposed traffic k-WASTE flow of requests and _{the k,} different requirements for quality of service requests k-th stream π _{k tr,} π _{k mp} - the required proportion of the lost appearances, the number of resource lines required to service a single application units k-th flow b _k, and storing the number of threads of applications for allocation of channel resource n, k = 1, 2, ..., n, the intensity of the offered traffic k-th flow of requests and _k , different requirements for the quality of service of requests of the k-th stream π _{k tr} , the number of units of the line resource needed to service one request of the k-th stream b _k , then estimate the necessary minimum amount of channel resource V and remember the necessary minimum amount of channel resource V, then based on estimated not is crawled minimum amount of channel resource is formed it is measured the intensity of the proposed traffic on the network and _{k cc} and the line speed on a single network telecommunications V _cc, stored intensity offered traffic on the network and _{k cc} and a channel resource of a single telecommunication network V _cc, control operational situation Communications on a communication network, predict changes in the intensity of the proposed traffic a _{k pp} and the capabilities of a single telecommunication network V _pp in time, erase the previous values b _k , π _{k mp} , n, and _k , V, write the updated values a _k , b _k , n, π _ktr , and _{k ol} , estimate the required minimum amount of channel resource V and remember it, compare the required minimum amount of channel resource V with the forecast results for the capabilities of a unified telecommunication network, _Vp , while if the the value of the necessary minimum amount of channel resource V more opportunities unified telecommunication network _prosp V, proceed to the formation of the required minimum amount of channel resource V, or if the results of comparing the estimated value neobhodimog minimum amount of channel resource V fewer opportunities single telecommunication network V _prosp, cut off the excess channel resource and return it in a single telecommunications network, wherein the disconnect primarily those channel units which monitoring results are in poor condition and (or) fold communications .

A new set of essential features allows achieving the indicated technical result due to the fact that by taking into account different requirements for the quality of service (the share of lost requests), managing admission to the network of different types of requests and evaluating reservation thresholds, the necessary channel resource is reduced, as well as the share of lost requests by adapting to the rapidly changing operational environment of communication on a communication network and a single telecommunication network using intensity prediction, th traffic and features a single telecommunications network.

The analysis of the prior art made it possible to establish that there are no analogues that are characterized by a combination of features that are identical to all the features of the claimed method (options) for monitoring and providing the required quality of customer service in multiservice networks. Therefore, the claimed invention meets the condition of patentability "novelty."

Search results for known solutions in this and related fields of technology in order to identify features that match the distinctive features of the claimed object from the prototype showed that they do not follow explicitly from the prior art. The prior art also did not reveal the popularity of the impact provided by the essential features of the claimed invention, the transformations on the achievement of the specified technical result. Therefore, the claimed invention meets the condition of patentability "inventive step".

The "industrial applicability" of the method (options) for monitoring and ensuring the required quality of customer service in multiservice networks is due to the presence of an element base, on the basis of which devices can be implemented that implement this method to achieve the purpose specified in the invention.

The claimed objects of the invention are illustrated by drawings, which show:

figure 1 - Block diagram of a sequence of actions that implement the first variant of the method;

figure 2 - Algorithm for estimating the channel resource and reservation thresholds;

figure 3 - Characteristics of the quality of service of different types of application flows when they are jointly serviced for the prototype method and the first variant of the claimed method (graphical explanation for example);

figure 4 - Block diagram of a sequence of actions that implement the second variant of the method;

figure 5 - Algorithm for estimating the channel resource;

6 - Device probabilistic forecasting;

7 - The algorithm of the device probabilistic forecasting;

Fig. 8 is a graph of the intensities of the proposed traffic flows of applications and the intensities of the proposed traffic flows of applications for the second variant of the method, taking into account forecasting;

figure 9 - Characteristics of the quality of service of different types of application flows during their joint servicing for the prototype method and the second variant of the claimed method at time t ₄ (graphical explanation for example);

figure 10 - Characteristics of the quality of service of different types of application flows when they are jointly serviced for the prototype method and the second variant of the claimed method at time t ₅ (graphical explanation for example);

11 - Graphs of line speed on a single telecommunication network and its values, taking into account forecasting.

The implementation of the inventive method in the first embodiment is as follows (figure 1).

Set and record the following source data:

- the number of application flow for the allocation of the channel resource n, k = 1, 2, ..., n (the number of services that the multiservice network will provide);

- the intensity of the proposed traffic of the k-th stream of applications a _k , k = 1, 2, ..., n (Stepanov S.N. Fundamentals of teletraffic of multiservice networks. - M.: Eco-Trends, 2010. - 392 p. S.116) ;

- different requirements for the quality of service of requests of the k-th stream π _{k tr} , where π _{k tr} ^{_ is the} required share of lost applications (Stepanov S.N. Basics of teletraffic of multiservice networks. - M.: Eco-Trends, 2010. - 392 p. S .111);

- the number of units of the line resource needed to service one application of the k-th stream b _k (Stepanov S.N. Fundamentals of teletraffic of multiservice networks. - M.: Eco-Trends, 2010. - 392 p. S.108).

The action associated with setting the source data is performed at the stage of network planning, the values of the source data are obtained on the basis of measurements, marketing research (Stepanov S.N. Fundamentals of teletraffic of multiservice networks. - M.: Eco-Trends, 2010. - 392 p. C .76-85), after which design documentation is developed. The initial data are recorded by means of actions related to their input through the data input device and direct recording of the voltage values of electrical signals to a storage device, which can be random access memory, hard disk memory, etc., and includes actions determined by the physics of processes in a specific storage device: reading, processing, writing, erasing, transmitting, receiving voltage values of electrical signals. Then, according to the algorithm for estimating the channel resource and the reservation thresholds (Fig. 2), the reservation thresholds (q _k ) are estimated (Lagutin BC, Stepanov S. N. Teletraffic of multiservice communication networks. - M .: Radio and communication, 2000. - 320 pp. C .134) and the required minimum amount of channel resource (V), where V is the line speed expressed in channel units (Stepanov S.N. Fundamentals of teletraffic of multiservice networks. - M.: Eco-Trends, 2010. - 392 p. C. 210), and remember them. Storage is performed on a storage device, which can be random access memory, hard drive memory, etc., and includes actions determined by the physics of processes in a specific storage device: reading, processing, writing, erasing, transmitting, receiving voltage values of electrical signals . Then form the required minimum amount of channel resource. The process of forming the required minimum amount of channel resource includes the following material actions on material objects: marching by forces and means, deploying communication facilities, putting into operation and intended use and (or) leasing of channels of a single telecommunication network, measurement of characteristics and parameters of channels of a single telecommunication networks, the intended use of channels of a single telecommunication network. In the process of functioning of the communication network, the occupied channel resource (r) is measured (Lagutin BC, Stepanov SN, Teletraffic of multiservice communication networks. - M.: Radio and Communications, 2000. - 320 pp. P.134-135) and information load. They accept applications from subscribers for the provision of the k-th service. The busy channel resource (r) is compared with the reservation thresholds (q _k ). These actions are performed in accordance with the Quality of Service (QoS) mechanisms in the control plane (ITU-T Rec. Y.1291 (05/2004)). Simultaneously with the comparison, one of three types of signals is generated: 1) the first type of signal, if the backup distributor is free and the main distributor is overloaded; 2) the second type of signal, if the backup distributor and the main distributor are overloaded; 3) the third type of signal, if the load has decreased and there is no need to use a backup path. Based on the comparison results, the transfer request is switched if the occupied channel resource is less than or equal to the reservation threshold for this type of request, or the service request is deleted if the occupied channel resource is greater than the reservation threshold for this type of request, it is considered lost and not renewed (Lagutin BC, Stepanov S.N. Teletraffic of multiservice communication networks.- M .: Radio and communication, 2000. - 320 p. S.135). Depending on the generated signal, the request for the backup channel is switched if the backup distributor is free and the main one is overloaded, or all applications for the main channel if the load has decreased and there is no need to use the backup channel, or they block applications with the lowest category if the main and backup distributors are overloaded .

The algorithm for estimating the channel resource and reservation thresholds in the first embodiment (Fig. 2) is intended to estimate the required minimum volume of the channel resource (V) and the reservation thresholds q _k taking into account the peculiarities of servicing heterogeneous applications in a multiservice network (applications with lesser requirements for the channel resource are supplanted from servicing applications with high requirements (Stepanov S.N. Fundamentals of teletraffic of multiservice networks. - M .: Eco-Trends, 2010. - 392 p. S.209)) and includes the following actions. In block 1, input of initial data: the number of application flows for allocation of a channel resource n; the intensity of the proposed traffic of the k-th stream of applications a _k , k = 1, 2, ..., n; different requirements for the quality of service of requests of the k-th stream π _{k tr} , k = 1, 2, ..., n; the number of units of the line resource needed to service one application of the k-th stream b _k , k = 1, 2, ..., n. In block 2, assign the value of the non-normalized probability in the zero state, i.e. when i = 0, the value is 1, i∈υ, υ = 1, 2, ..., V. In block 3, assign i the value 1. In block 4, determine the value of the indicator function I (i - b _k ≥0) from the equality ib _k ≥0, if equality is fulfilled, then go to block 5, if equality is not fulfilled, then go to block 6. In block 5, assign the value of indicator function 1. In block 6, assign the value of indicator function 0. In block 8, calculate the abnormal probability P ( i) according to the formula

In block 8, the calculation of the normalization constant N by the formula

In block 9, the calculation of normalized probabilities p (i) by the formula

In block 10, the calculation of the percentage of lost bids π _k according to the formula

In block 11, the comparison of the share of lost bids π _k with the desired value of the share of lost bids π _{k tr} , if π _{k is} greater than π _{k tr} , go to block 12, if not, go to block 13. In block 12, increase the value of i by one, those. i + 1, and go to block 4. In block 13, assign the initial value of the threshold a reservation q _k , the value V, where V is i at which the condition in block 11 starts to fail. In block 14, the cycle for r, r ∈ υ, from 1 to 15 V. In block indicator function definition values I0≤rb _k ≤q _k  of equality 0≤rb _k ≤q _k, if the equality holds, then moves to block 16, if the equality is not satisfied, then the transition to block 17. In block 16, assign the value of the indicator function 1. In block 17, assign the value of the indicator function 0. In block 18, the calculation of the abnormal probability P (r) by the formula

In block 19, the calculation of the normalization constant N by the formula

In block 20, the calculation of normalized values of the probabilities p (r) by the formula

In block 21, the calculation of the percentage of lost bids π _{k the} formula

In block 22, a comparison of the percentage of lost bids (bids of the type with b_k maximum) π_k with the required value of the percentage of lost bids π_{k tr}if the condition is met, go to block 24, if the condition is not met, go to block 23. In block 23, check the condition if all π_k equal to the required values of the share of lost bids π_{k tr}, if yes, go to block 31, if not, go to block 25. In block 24, return to those q values_k the next step back, on which all π_k less than or equal to the required values of the percentage of lost bids π_{k tr}, and with these values of q_kgo to block 31. In block 25, a comparison of the percentage of lost bids π_k with the required value of the percentage of lost bids π_{k tr}if π_k less than π_{k tr}, go to block 26, if not, go to block 27. In block 26, decrease q_k per unit, i.e. q_k-1, and go to block 30. In block 27, the comparison in turn is π_k with the required value of the percentage of lost bids π_{k tr}if q_kequal to π_{k tr}, go to block 28, if not, go to block 29. In block 28, assign q_k its current value, i.e. leave, do not change. In block 29, increase the q value_k per unit, i.e. q_k+1, and go to block 30. In block 30, the counter of the number of steps, then go to block 14. In block 31, the percentage of lost requests π_k with the required value of the percentage of lost bids π_{k tr}if π_k less than or equal to π_{k tr}, go to block 32, if not, go to block 34. In block 32, reduce the value of V by one, i.e. V-1. In block 33, the calculation of the percentage of lost requests π_k according to the formula

In block 34, increase the value of V by one, i.e. V + 1. In block 35, the output of the values of the reservation thresholds q _k and the required minimum amount of channel resource V.

The implementation of the inventive method in the second embodiment is as follows (figure 4). Set and record the following source data:

- the number of application flow for the allocation of the channel resource n, k = 1, 2, ..., n (the number of services that the multiservice network will provide);

- the intensity of the proposed traffic of the k-th stream of applications a _k , k = 1, 2, ..., n (Stepanov S.N. Fundamentals of teletraffic of multiservice networks. - M.: Eco-Trends, 2010. - 392 p. S.116) ;

- different requirements for the quality of service of requests of the k-th stream π _{k tr} , where π _{k tr} is the required share of lost applications (Stepanov S.N. Basics of teletraffic of multiservice networks. - M.: Eco-Trends, 2010. - 392 p. S .111);

- the number of units of the line resource needed to service one application of the k-th stream b _k (Stepanov S.N. Fundamentals of teletraffic of multiservice networks. - M.: Eco-Trends, 2010. - 392 p. S.108).

The action associated with setting the source data is performed at the stage of network planning, the values of the source data are obtained on the basis of measurements, marketing research (Stepanov S.N. Fundamentals of teletraffic of multiservice networks. - M.: Eco-Trends, 2010. - 392 p. C .76-85), after which design documentation is developed. The initial data are recorded by means of actions related to their input through the data input device and direct recording of the voltage values of electrical signals to a storage device, which can be random access memory, hard disk memory, etc., and includes actions determined by the physics of processes in a specific storage device: reading, processing, writing, erasing, transmitting, receiving voltage values of electrical signals. Then, according to the channel resource estimation algorithm (Fig. 7), the required minimum channel resource volume (V) is estimated, where V is the line speed expressed in channel units (Stepanov S.N. Basics of teletraffic of multiservice networks. - M.: Eco-Trends, 2010. - 392 p. S.210), and remember it. Storage is performed on a storage device, which can be random access memory, hard drive memory, etc., and includes actions determined by the physics of processes in a specific storage device: reading, processing, writing, erasing, transmitting, receiving voltage values of electrical signals . Then form the required minimum amount of channel resource. The process of forming the required minimum amount of channel resource includes the following material actions on material objects: marching by forces and means, deployment of funds, commissioning and intended use and (or) leasing of channels of a single telecommunication network, measurement of characteristics and parameters of channels of a single network telecommunications, the intended use of channels of a single telecommunication network. They monitor the status of the main and backup paths without disconnecting subscribers. The intensity of the proposed traffic on the network is measured for each flow of applications (and_{k ss}) and line speed on a single telecommunication network (V_cc) (these actions are performed in accordance with the Quality of Service (QoS) mechanisms in the management plane (ITU-T Rec. Y.1291 (05/2004))), remember this data. They also monitor the operational situation of communication on the communication network. Predict changes in the intensity of the proposed traffic (and_{k ol}) and the capabilities of a unified telecommunication network (V_for) in time. Prediction is carried out on the basis of well-known methods (Chuev Yu.V., Mikhailov Yu.B. Forecasting in military affairs. M., Military Publishing House, 1975. 279 p. S. 137-271), as an option can be performed according to the scheme presented on Fig. 8 (Ivanov V.A., Grechishnikov E.V., Dvilyansky A.A., Belov A.S. Device for active protection and ensuring technical readiness of distributed LAN elements under external destructive influences. Patent No. 2316810 of 02/10/2008 ) Erase previous b values_k, π_{k tr}, n, and_k, V. Erasure includes actions on the voltage values of electrical signals, determined by the physics of the processes in a particular storage device. Record, taking into account the control of the operational situation of communication on the communication network, the updated values a_kb_k, n, π_{k tr}, and taking into account the forecasting, the value of a_{k ol}. Data recording is performed through actions related to their input through the data input device and direct recording to the storage device, which can be random access memory, hard disk memory, etc., and includes actions determined by the physics of processes in a specific storage device: reading, processing, writing, erasing, transmitting, receiving voltage values of electrical signals. In this case, if the operational situation in the communication network has not changed, the values of b_k, n, π_KTRare left the same, but a_k takes the value a_{k ol}. If the operating environment has changed (a new subscriber has appeared who needs to provide new services or old services, but with different quality requirements (π_{k tr}), or vice versa, the subscriber has changed his location and there is no need to provide any services or the quality of their provision has changed, etc.), values a_kb_k, n, π_{k tr} refined (some values become new or remain old, or some values are added or deleted), while a_k takes the value a_{k ol}if the number of application flows for allocation of a channel resource has not changed, or a new value if the number of application flows for allocation of a channel resource has changed. Then evaluate the new value of V (figure 5) and remember it. Storage is performed on a storage device, which can be random access memory, hard drive memory, etc., and includes actions determined by the physics of processes in a specific storage device: reading, processing, writing, erasing, transmitting, receiving voltage values of electrical signals . Compare V to V_for, moreover, if according to the results of comparing the channel resource it is not enough, i.e. V> v_forthen proceed to the formation of the required minimum amount of channel resource from the calculation of the addition ΔV_one channel units, where ΔV_one= V - V_for. Or if, according to the results of the comparison, the volume of the channel resource obtained from the forecast results is more than necessary, i.e. V <v_for, then disable the extra channel resource ΔV₂ and return it to a single telecommunication network, where ΔV₂= V_for-V. In this case, first of all, those channel units that, according to the results of control, are in an emergency state and (or) are shutting down communications are disconnected.

The channel resource estimation algorithm (Fig. 5) is intended to estimate the required minimum volume of the channel resource (V) and includes the following actions. In block 1, input of initial data: the number of application flows for allocation of a channel resource n; the intensity of the proposed traffic of the kth order flow a _k , k = 1, 2, ..., n; different requirements for the quality of service of requests of the k-th stream π _{k tr} , k = 1, 2, ..., n; the number of units of the line resource needed to service one application of the k-th stream b _k , k = 1, 2, ..., n. In block 2, assign the value of the non-normalized probability in the zero state, i.e. when i = 0, the value is 1, i∈υ, υ = 1, 2, ..., V. In block 3, assign i the value 1. In block 4, determine the value of the indicator function I (i - b _k ≥0) from the equality ib _k ≥0, if equality is fulfilled, then go to block 5, if equality is not fulfilled, then go to block 6. In block 5, assign the value of indicator function 1. In block 6, assign the value of indicator function 0. In block 8, calculate the abnormal probability P ( i) according to the formula

In block 8, the calculation of the normalization constant N by the formula

In block 9, the calculation of normalized probabilities p (i) by the formula

In block 10, the calculation of the percentage of lost bids π _k according to the formula

In block 11, the comparison of the share of lost bids π _k with the desired value of the share of lost bids π _{k tr} , if π _{k is} greater than π _{k tr} , go to block 12, if not, go to block 13. In block 12, increase the value of i by one, those. i + 1, and go to block 4. In block 13, assign the initial value of the threshold a reservation q _k , the value V, where V is i, at which the condition in block 11 begins to fail. In block 14, the cycle for r, r∈υ, starting from 1 to V. In block 15, determining the value of the indicator function I (0≤r - b _k ≤q _k ) from the equality 0≤rb _k ≤q _k , if the equality is fulfilled, then go to block 16, if the equality is not fulfilled, then go to block 17. In block 16, assign the value of the indicator function 1. In block 17, assign the value of the indicator function 0. In block 18, the calculation of the abnormal probability P (r) by the formula

In block 19, the calculation of the normalization constant N by the formula

In block 20, the calculation of normalized values of the probabilities p (r) by the formula

In block 21, the calculation of the percentage of lost bids π _k according to the formula

In block 22, a comparison of the percentage of lost bids (bids of the type with b_k maximum) π_k with the required value of the percentage of lost bids π_{k tr}if the condition is met, go to block 24, if the condition is not met, go to block 23. In block 23, check the condition if all π_k equal to the required values of the share of lost bids π_{k tr}, if yes, go to block 31, if not, go to block 25. In block 24, return to those q values_k the next step back, on which all π_k less than or equal to the required values of the percentage of lost bids π_{k tr}, and with these values of q_kgo to block 31. In block 25, a comparison of the percentage of lost bids π_k with the required value of the percentage of lost bids π_{k tr}if π_k less than π_{k tr}, go to block 26, if not, go to block 27. In block 26, decrease q_k per unit, i.e. q_k-1, and go to block 30. In block 27, the comparison in turn is π_k with the required value of the percentage of lost bids π_{k tr}if π_kequal to π_{k tr}, go to block 28, if not, go to block 29. In block 28, assign q_k its current value, i.e. leave, do not change. In block 29, increase the q value_k per unit, i.e. q_k+1, and go to block 30. In block 30, the counter of the number of steps, then go to block 14. In block 31, the percentage of lost requests π_k with the required value of the percentage of lost bids π_{k tr}if π_k less than or equal to π_{k tr}, go to block 32, if not, go to block 34. In block 32, reduce the value of V by one, i.e. V-1. In block 33, the calculation of the percentage of lost requests π_k according to the formula

In block 34, increase the value of V by one, i.e. V + 1. In block 35, the output value of the required minimum amount of channel resource V.

The device of probabilistic forecasting (Fig.6) is a known device (Diagnostic tools: Reference / VV Klyuev and others. Under the general editorship of VV Klyuev. - M.: Engineering, 1989. - 672 S.) (p. 158-159, Fig. 17), is intended to predict the intensities of the proposed traffic (a _{k ol} ), as well as the capabilities of a unified telecommunication network (V _ol ) by channel resource. It includes a switching and measuring unit (BKI) 1, a memory unit (BP) 2, a weight coefficient block (BVK) 3, a block for calculating the probabilistic characteristics of a priori information (BV1) 4, a block for calculating conditional posterior probabilities (BV2) 5, a correction block results (BKR) 6, display units (BI) 7 and control (BU) 8.

The algorithm of the device probabilistic forecasting (Fig.7) consists of the following actions. In block 1 input of the initial data. In block 2 monitoring of the communication network and a single telecommunication network. In block 3, the monitoring results are recorded in the memory block (intensity of the incoming load, line speed of the unified telecommunication network). In block 4, the calculation (prediction) of the intensities of the proposed traffic and the capabilities of the telecommunication network for the channel resource. In block 5, the output of the prediction results to block 11 of the flowchart that implements the second variant of the method (figure 4).

The claimed method (options) for monitoring and ensuring the required quality of customer service in multiservice networks provides a reduction in the required amount of channel resources by controlling the admission of incoming requests of different types, taking into account different requirements for the quality of their service when evaluating reservation thresholds and the required minimum amount of channel resources, as well as reducing the share of lost applications due to adaptation to the rapidly changing operational environment of communication on the communication network and the unified electric network tie with forecasting.

The validity of the developed method in the first embodiment was checked by modeling the functioning of the multiservice network with the following initial data: n = 10, b ₁ = 1, b ₂ = 2, b ₃ = 5, b ₄ = 10, b ₅ = 12, b ₆ = 15, b ₇ = 20, b ₈ = 22, b ₉ = 25, b ₁₀ = 30, a ₁ = 20, a ₂ = 15, a ₃ = 13, a ₄ = 11, a ₅ = 10, a ₆ = 9, a ₇ = 7, a ₈ = 6, a ₉ = 5, a ₁₀ = 4, π _1tp = 0.052, π _2tp = 0.02, π _3tp = 0.04, π _4tr = 0.01, π _5tp = 0.052, π _6tp = 0.03, π _7tp = 0.02, π _8tp = 0.01, π _9tp = 0.02, π _10tp = 0.03.

The simulation results are shown in figure 3, which presents the characteristics of the quality of service of different types of application flows when they are jointly serviced for the prototype method and the first variant of the claimed method. The results of the above calculations were obtained by the authors on the basis of a PC program in the Mathcad environment.

The attainability of the claimed technical result on the example of a multiservice communication network node is confirmed by the calculations below.

For the prototype method, with the initial data: n = 10, b ₁ = 1, b ₂ = 2, b ₃ = 5, b ₄ = 10, b ₅ = 12, b ₆ = 15, b ₇ = 20, b ₈ = 22, b ₉ = 25, b ₁₀ = 30, a ₁ = 20, a ₂ = 15, a ₃ = 13, a ₄ = 11, a ₅ = 10, a ₆ = 9, a ₇ = 7, a ₈ = 6, a ₉ = 5, a ₁₀ = 4, π _1tp = 0.052, π _2tp = 0.02, π _3tp = 0.04, π _4tp = 0.01, π _5tp = 0.052, π _6tp = 0.03 , π _7tp = 0.02, π _8tp = 0.01, π _9tp = 0.02, π _10tp = 0.03, the value of the required minimum amount of channel resource: V = 1266.

For the proposed method in the first embodiment, with the same initial data: n = 10, b ₁ = 1, b ₂ = 2, b ₃ = 5, b ₄ = 10, b ₅ = 12, b ₆ = 15, b ₇ = 20, b ₈ = 22, b ₉ = 25, b ₁₀ = 30, a ₁ = 20, and ₂ = 15, a ₃ = 13, and ₄ = 11, a ₅ = 10, and ₆ = 9, and ₇ = 7, and ₈ = 6, and ₉ = 5, and ₁₀ = 4, π _1tp = 0.052, π _2tp = 0.02, π _3tp = 0.04, π _4tp = 0.01, π _5tp = 0.052, π _6tp = 0.03, π _7tp = 0.02, π _8tp = 0.01, π _9tp = 0.02, π _10tp = 0.03, the value of the required minimum amount of channel resource V = 1189. Thus, the difference between the required minimum amount of channel resource for the prototype method and the proposed method in the first embodiment is calculated from the expression: ΔV = 1266-1189 = 77, and expressed as a percentage: ΔV = 77 · 100% / 1266 = 6%.

From the above data it follows that after applying the inventive method in the first embodiment, the need for channel resource decreased by 6%.

The validity of the developed method in the second embodiment was checked by modeling the functioning of the multiservice network under the following conditions. Let the following initial data be specified in a multiservice network in the time interval from 0 to t ₄ : n = 4, b ₁ = 30, b ₂ = 15, b ₃ = 10, b ₄ = 1, a ₁ = 6, and ₂ = 10 , and ₃ = 14, and ₄ = 20, π _1tp = 0.05, π _2tp = 0.03, π _3tp = 0.02, π _4tp = 0.01, the planned speed of the unified telecommunication network line is V ₁ = 635 ( in which the requirements for the share of lost applications for the prototype method are met), the measured line speed of the unified telecommunication network V _cc and the results of predicting the speed of the line of the unified telecommunication network V _p change, as shown in Fig. 11, the measured intensity of the proposed traffic of the application flows a _{k c c} and the results of predicting the intensity of the proposed traffic of the application flows a _{k pr} vary as shown in Fig. 8. As a result of the changing operational environment of communication on the communication network after time U, the initial data changed and took the following values: n = 5, b ₁ = 30, b ₂ = 15, b ₃ = 10, b ₄ = 1, b ₅ = 13 , a ₁ = 6, a ₂ = 10, a ₃ = 14, a ₄ = 20, a ₅ = 12, π _1tp = 0.05, π _2tp = 0.03, π _3tp = 0.02, π _4tp 0.01, π _5tp = 0.04. Let us evaluate the quality of service parameters (the share of lost applications) for the prototype method and for the proposed method in the second embodiment at time t ₄ and t ₅ .

The results of modeling and characteristics of the quality of service of different types of application flows during their joint servicing for the prototype method and the second variant of the claimed method at time t ₄ are shown in Fig. 9, with initial data at time t ₄ : n = 4, b ₁ = 30 , b ₂ = 15, b ₃ = 10, b ₄ = 1, a _1cc = 7, and _2cc = 13, a _3cc = 11, and _4cc = 16, π _1tp = 0.05, π _2tp = 0.03, π _3tp = 0.02, π _4tr = 0.01, the line speed of the unified telecommunication network V _{cc t4} = 630 (Fig. 11). The results of predicting the speed of the line of a unified telecommunication network _{Vp t4} = 629 (Fig. 11), the results of predicting the intensities of the proposed traffic of application flows a _{1pr t4} = 7, a _{2pr t4} = 13, and _{3pr t4} = 11, and _{4pr t4} = 15, in the result of the addition of ΔV _{1 t4} channel units at time t ₄ , where ΔV _{1 t4} = V _t4 - _{Vp t4} , and V _t4 is the result of evaluating the new value of V and V _t4 = 673 channel units, ΔV _{1 t4} = 673 - 629 = 44, at time t _{4 the} value of the available channel resource volume V _{2 t4} = 630 + 44 = 674.

The simulation results and characteristics of the quality of service of different types of application flows during their joint servicing for the prototype method and the second variant of the claimed method at time t ₅ are shown in Fig. 10, with initial data at time t ₅ : n = 5, b ₁ = 30 , b ₂ = 15, b ₃ = 10, b ₄ = 1, b ₅ = 13, a _1cc = 7, and _2cc = 13, a _3cc = 11, a _4cc = 16, and _5cc = 13, π _1tp = 0 , 05, π _2tp = 0.03, π _3tp = 0.02, π _4tp = 0.01, π _5tp = 0.04, the speed of the unified telecommunication network line is V _{cc t5} = 620 (Fig. 11). The results of predicting the speed of the line of a unified telecommunication network _{Vp t5} = 615 (Fig. 11), the results of predicting the intensities of the proposed traffic of application flows a _{1pp t5} = 6, and _{2pp t5} = 11, a _{3pp t5} = 12, and _{4pr t5} = 14, and _{5pr t5} = 10 as a result of adding ΔV _{1 t5} channel units to time t ₅ , where ΔV _{1 t5} = V _t5 - V _{p t5} , and V _t5 is the result of evaluating the new value of V and V _t5 = 746 channel units, ΔV _{1 t4} = 746 - 615 = 131, by the time t _{5 the} value of the available channel resource volume V _{2 t5} = 620 + 131 = 751.

The results of the calculations were obtained by the authors on the basis of the program for PVEM in Mathcad environment.

Thus, the difference between the share of lost applications for the prototype method and the proposed method in the second embodiment at time t ₄ and t _{5 is} calculated from the following expressions. The difference between the share of lost orders for each thread separately at time t ₄ :

Δπ _{1 t4} = 0.093 - 0.05 = 0.043,

Δπ _{2 t4} = 0.043 - 0.03 = 0.013,

Δπ _{3 t4} = 0.028 - 0.02 = 0.008,

Δπ _{4 t4} = 2.712 · 10 ^-3 - 9.932 · 10 ^-3 = -7.22 · 10 ^-3 .

The total difference between the share of lost applications at time t ₄ :

Δπ _{total t4} = 0.043 + 0.013 + 0.008 + (- 7.22 · 10 ^-3 ) = 0.05678.

The difference between the share of lost orders for each thread separately at time t ₅ :

Δπ _{1 t5} = 0.327 -0.127 = 0.2,

Δπ _{2 t5} = 0.172 -0.074 = 0.098,

Δπ _{3 t5} = 0.117-0.049 = 0.068,

Δπ _{4 t5} = 0.012 - 0.026 = - 0.014,

Δπ _{5 t5} = 0.15 -0.1 = 0.05.

The total difference between the share of lost applications at time t ₅ :

Δπ _{total t5} = 0.2 + 0.098 + 0.068 + (- 0.014) + 0.05 = 0.402.

The average difference between the share of lost applications in the considered period of time: Δπ _{cp t4-5} = (0.05678 + 0.402) / 2 = 0.23, and expressed as a percentage Δπ _{cp t4-5} = 0.22 · 100% = 23% .

From the above data it follows that after the application of the claimed method in the second embodiment, the percentage of lost applications decreased by 23%.

The above examples clearly illustrate the effect of the application of the method (options) for monitoring and providing the required quality of customer service in multiservice networks. Thus, the claimed technical result is achieved.

Claims (2)

1. A method for monitoring and ensuring the required quality of customer service in multiservice networks, which consists in measuring the information load, generating one of three types of control signals, switching the request for the backup channel if the backup distributor is free and the main one is overloaded, or all applications for main channel, if the load has decreased and there is no need to use a backup channel, while applications with the lowest category are blocked, if the main and backup distributors are overloaded, different m, which first sets the number of application flows for the allocation of the channel resource k, k = 1, 2, ..., n, the intensity of the proposed traffic of the k-th application flow and _k , different requirements for the quality of service of applications of the k-th flow π _{k tr} , π _{k tr} - the required share of lost applications, the number of units of the line resource needed to serve one application of the k-th stream b _k , and the number of application flows for allocation of the channel resource k, k = 1, 2, ..., n, the intensity of the proposed traffic k th flow of requests and _k, different requirements for quality of service applications π _kfr, the number of units ESOURCES lines required to service a single application k-th flow b _k, then evaluated thresholds redundancy q _k and the required minimum amount of channel resource V and stored thresholds redundancy q _k and the required minimum amount of channel resource V, then based on the estimated required minimum amount of channel they form the resource, measure the occupied channel resource r, receive an application from the subscriber for the kth service, compare the occupied channel resource with the reservation thresholds, while the results are comparable Requirements switch the transfer request if the occupied channel resource is less than or equal to the reservation threshold for this type of request, or delete the service request if the occupied channel resource is greater than the reservation threshold for this type of request. 2. A method for monitoring and ensuring the required quality of customer service in multiservice networks, which consists in monitoring the status of the main and backup paths without disconnecting subscribers, characterized in that the number of application flow for channel resource allocation k, k = 1, 2 is first set , ..., n, the intensity of the proposed traffic of the k-th stream of applications a _k , different requirements for the quality of service of applications of the k-th stream π _{k tr} , π _{k tr} - the required share of lost applications, the number of units of the line resource required for servicing the bottom of the application of the k-th flow b _k , and remember the number of application flows for the allocation of the channel resource k, k = 1, 2, ..., n, the intensity of the proposed traffic of the k-th application flow a _k , different requirements for the quality of service of requests of the k-th flow π _{k tr} , the number of units of the line resource needed to serve one request of the k-th stream b _k , then the necessary minimum volume of the channel resource V is estimated and the necessary minimum volume of the channel resource V is stored, then it is formed on the basis of the estimated necessary minimum volume of the channel resource , measuring the intensity of the proposed traffic on the network and _{k ss} and line speed on a single network telecommunications V _cc, stored intensity offered traffic on the network and _{k ss} and a channel resource of a single telecommunication network V _cc, control operational situation of communication in a communication network, predicting intensity changes proposed traffic and _{k pr} and possible a single network telecommunications V _prosp time, erase previous values b _k, π _{k tr,} k, a _k, V, recorded specified values a _k, b _k, π _kfr and _{k pr,} estimate the required minimal volume channel Foot resource V and memorize it, compared to the required minimum amount of channel resource V with the results of a single network capacity forecast Telecommunication V _prosp, while, if the results of comparing the estimated value of the required minimum amount of channel resource V more opportunities unified telecommunication V _prosp network, go to the formation of the required minimum volume of the channel resource V, or, if, according to the results of the comparison, the estimated value of the required minimum volume of the channel resource V is less than V _prosp second telecommunication network channel resource disconnected once and return it in a single telecommunications network, wherein the first disable those channel units which monitoring results are in poor condition and (or) fold communications.

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