RU2207723C1 - Method of distribution of resources in electric communication system with multiple access - Google Patents

Abstract

FIELD: radio engineering, specifically, distribution of carrying capacity of electric communication system of multiple access, systems controlling telecommunication networks. SUBSTANCE: proposed method realizes predicted number of requests of users for transmission of speech messages in due time interval of operation of electric communication system and for redistribution of channel resource. EFFECT: increased carrying capacity of system, improved quality of servicing thanks to more accurate, advanced determination of probable value of number of requests on transmission of speech messages. 2 cl, 3 dwg

Description

 The invention relates to a method for distributing the capacity of multiple access telecommunication systems and can be used in telecommunication network management systems.

A known method of controlling the workload in a mobile communication network (see, for example, RF patent 2147795, IPC ⁷ N 04 V 7/26, N 04 Q 7/20, 04/20/00, 20), characterized in that the mobile switching center the communications form, at predetermined time intervals, a measured graph file that is transmitted to the control system and subsequently processed for visual graphical representation on the map image, based on which a decision is made to manage the workload.

 However, the known method has disadvantages associated with possible poor use of system bandwidth and poor service, since the schedule estimate for the previous time interval is used for control.

There is also known a method implemented in a device for controlling the transmission of packet information over a radio channel (see RF patent 2168282, IPC ⁷ H 04 E 29/12, 7/00, 05/27/01). In a well-known analogue, the load parameters are evaluated during the operation of the transmission system and, according to the results of their evaluation, the order of servicing data packets is adapted.

 The disadvantage of this method is the possible poor use of system bandwidth and the deterioration of service requests, because the control uses the schedule estimate for the previous time interval. At the same time, load parameters of other priorities are not used for resource allocation.

Closest to the technical nature of the claimed is a method for the dynamic allocation of the bandwidth of radio channels in systems with multiple access with time division channels (see RF patent 2153240, IPC ⁷ H 04 Q 7/34, 07.20.00). The prototype method consists in setting the initial number of time intervals for transmitting voice messages and data packets at which the maximum capabilities of the system for transmitting information are provided. Count the number of occupied time slots for transmitting voice messages and data packets for a fixed period of time. The obtained values of the occupied time intervals for the period of measurement for transmitting information are transmitted via control channels. The number of occupied time intervals for the measurement period is compared with the previously set one, according to the results of comparison, the number of time intervals for transmitting voice messages and / or data packets is changed, the new value of the number of time intervals for transmitting voice messages and (or) data packets is brought to the base station.

 However, the prototype method also has a drawback - a possible poor use of system bandwidth and poor service requests. This is due to the relatively low accuracy of predicting the required resource for subsequent time intervals of the system. Indeed, the decision to reallocate resources for the transmission of voice messages and data packets is made on the basis of the previously measured value of the number of applications received for a given time interval, while the possible variability of the schedule is ignored, which leads to an inadequate distribution of system capacity. For the next measurement interval, a resource is allocated that corresponds to the number of requests in the last time interval, while in reality, the system may require another part of the resource to provide services with a given quality. Under these conditions, in most cases, an unsatisfactory redistribution of the resource between voice messages and data packets occurs, which impairs the use of the bandwidth of the telecommunication system with multiple access and can lead to poor service requests.

 The purpose of the proposed technical solution is to develop a method for distributing the bandwidth of a telecommunication system with multiple access, which will increase the use of system bandwidth and improve the quality of service requests due to a more accurate, faster determination of the probable value of the number of requests for voice messages.

To achieve the specified technical result in the known method of dynamic resource allocation in a multi-access telecommunication system, a portion of the total system resource is preliminarily allocated to serve N ₀ requests for voice messages, where N ₀ <N _max , N _max is the maximum number of requests for transmission voice messaging system, the remainder of the total system resources allocated to the transmission of data packets measured in a predetermined interval T ₀ N number of requests for transmission _of speech messages received by comparing the number N _of predefined queries and N _0, whereupon the overall system redistribute resource for transmission of voice messages and data packets additionally measured at time intervals T L ₀ number of requests for voice communications. Then they predict for the next time period T _{0 the} number of possible requests N _prog for the transmission of voice messages. Then compare the predicted number of requests N _prog with a predefined N ₀ . When the condition N ₀ <N _prog <N _{max is} fulfilled, the next time interval of the system operation allocates a part of the resource necessary for servicing N _prog requests, and the rest for transmitting data packets. In case N _prog ≥N _max , the entire system resource is allocated for servicing voice transmission requests.

The number L of time intervals T ₀ choose from three to five.

 Prediction of the number of possible requests for voice messages.

The number L of time intervals T ₀ choose from three to five.

или по формуле

где

- целая часть числа, st_H,n-1 - квантиль стандартизованного распределения Стьюдента с коэффициентом надежности Н и (L-1) степенью свободы; S_L - сумма квадратов отклонений измеренных и прогнозных значений на L временных отрезках.Prediction of the number of possible requests for voice messages N _prog for the i-th time interval T ₀ , where i = L + 1, L + 2, L + 3, ..., are calculated by the formula

or according to the formula

Where

- the integer part of the number, st _{H, n-1} is the quantile of the standardized Student distribution with a reliability coefficient H and (L-1) degree of freedom; S _L - the sum of the squares of the deviations of the measured and predicted values on L time intervals.

 Thanks to the new set of essential features, due to the introduction of a stage of more accurate prediction of the probable number of requests for the next time interval of the system’s operation, better use of the common resource of information channels is achieved in it, which leads to an increase in its throughput in the dynamics of operation, subject to the specified requirements for the quality of voice message transmission.

 The analysis of the prior art made it possible to establish that analogues that are characterized by a combination of features identical to all the features of the claimed technical solution are absent, which indicates the compliance of the claimed device with the patentability condition of "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 transformations to achieve the specified technical result. Therefore, the claimed invention meets the condition of patentability "inventive step".

The claimed device is illustrated by diagrams:
figure 1 is a functional diagram of a telecommunication system with multiple access and registration of user requests;
FIG. 2 is a graph of changes in the real number of requests and predicted by the claimed method;
FIG. 3 is a graph of changes in the real number of requests and predicted by the last value.

 The essence of the proposed method and the possibility of its technical implementation is explained as follows.

 It is known that the operational control of flows and channel resources in communication networks is based on estimates of the input load obtained as a result of measuring the number of requests or occupancy of serving devices for a certain period of time (see Kornyshev Yu.N., Fan G.L. Information Distribution Theory. - M .: Radio and communication, 1985, p. 45-49). Most often used control, which can be attributed to adaptive, since the distribution of the channel resource is carried out after changing the parameters of the input streams. With delays in the reaction to changes, the control efficiency turns out to be low and often loses all sense, since the estimated parameters manage to change during the reaction. This requires the introduction of redundancy in the channel capacity, calculated for the worst case (for example, for the hour of maximum load), that is, leads to poor use of the system.

 More preferable is the control according to the predicted estimates of the incoming load, which provides a margin in time for the implementation of the control. Obviously, the feasibility and feasibility of solving this problem depends on the nature of the change in time of the predicted process.

 The implementation of the proposed method can be considered by example.

In a modern telecommunication network (radio, wire, optical fiber, waveguide) with multiple access, a variant of the structural diagram of which is shown in Fig. 1, the values of the number of requirements N _s arriving at the central station of multiple access for a given time interval T ₀ are available for monitoring and registration. In general, a circuit of such a network includes:
user equipment 9, consisting of a transmitter 1 with a query generator 2, a receiver 3 with a query receiver 4;
the equipment of the central station, consisting of a transmitter 1 with a query generator 2, a receiver 3 with a query receiver 4, a recording device 5 and a control device 6;
control channel 7 and resource information channels 8.

At the initial stage of operation, the control device 6 of the central station 10 allocates for the transmission of voice messages the number of information channels 8 necessary to provide an average number of user requests N ₀ , the remaining channels are reserved for transmitting data packets. Upon receipt of a request for the transmission of information of a certain type in the user equipment 9, the query generator 2 generates a request indicating the time of receipt of the application and the type of information transmitted. The generated request is transmitted by the transmitter 1 of the user equipment 9 via the control channel 7 to the receiver 3 of the central station 10 of the multiple access telecommunication network. The receiver 3 selects the received request and transmits it to the request receiver 4, where the information about the user's application is extracted and brought to the recording device 5 of the equipment of the central station 10. In the recording device, information is recorded in the database table indicating the time of receipt of the request, user number, its priority (if installed), the type of information transmitted. The specified information is transmitted to the control device 6, which, in accordance with the current state of the system, makes a decision to allocate information channel 8. The decision is transmitted to the query generator 2 and the query receiver 4 of the central station 10. In the absence of free information channels, a command is sent to the recording device 5 changes to a previously made record, the denial of service time and the reason (lack of free channels) are added to it. If there is a free information channel in the query generator 2, a request is generated indicating the user number, the number of the allocated information channel 8: if at the current moment the entire resource of the information channels is used up, then a denial of service is generated. The generated request is transmitted to the transmitter 1 of the equipment of the central station 10, which transmits it via the control channel 7 to the receiver 3 of the user equipment 9. At the same time, information received from the control device 6 in the receiver of requests 4 of the equipment of the central station 10 generates and sends a command to the receiver 3 to change mode of operation in accordance with the received command.

 The request received by the receiver 3 of the user equipment 9 is transmitted to the request receiver 4, where information about the provided information channel or denial of service is highlighted. In the case of allocation of the information channel to the receiver 3 and transmitter 1, a command is received to change the operating mode: in case of denial of service, a command is sent to bring the received information to the user.

 After changing the operating modes of transmitters and receivers, an information exchange is conducted on a dedicated channel. The time of the beginning of information exchange, the type of transmitted information, the user number, and the number of the allocated channel are transmitted by the request receiver 4 of the equipment of the central station 10 to the recording device 5, where the listed parameters are written to the database table.

At the end of the information exchange, the query generator 2 of the user equipment 9 generates a command to end the use of the dedicated channel, which is received by the receiver 3 of the central station equipment and transmitted to the query receiver 4, where information is generated that is transmitted for recording to the recording device 5. In the recording device, the received information is added to the previously generated database table record with the end time of the use of the selected channel. Similarly, information channels are allocated to other network users. The information accumulated in the database of the recording device 5 is transmitted for analysis in order to determine the quality of service to the control device 6 of the central station of the multiple access network. The receipt of this information can occur both upon request from the control device 5, and initiatively at predetermined time intervals T ₀ . In the case of reducing the quality of service, ie. E, detecting inconsistencies between the reserved number of data channels and actual necessary to provide received user requests N _of the transmission of voice messages over a specific time interval T _0, the control unit 5 generates a command to reallocate the channel resources between voice messaging and data packets.

Information on the number of requests N _s for conducting information exchange received for a given time interval can be used in making decisions on changing the number of allocated resources of the system’s information channels in order to transfer information of various types and switch an unused channel resource in the interests of servicing other types of information load, for example data packets. Observations thus form a time series. In this case, we are talking about short-term forecasting, so the time intervals T _{0 are} very short and can range from 15 minutes to an hour (see Kornyshev Yu.N., Fan GL, Theory of Information Distribution. - M.: Radio and Communications , 1985, p. 45). Considering that the measurement results quickly become outdated, it is advisable to use a limited number of them, from three to five, for example, in the interval of the last hour of observation to make a decision. The final choice of the time interval T ₀ and the number of such time intervals L, depends on the specific situation, the purpose of the network, its structure.

 The inventive method proposes to distribute the available resource of information channels between the transmission of voice messages and data packets based on a previously predicted number of information channels for transmitting voice messages.

 An example of the implementation of the proposed method and the actual process of receiving requests for the transmission of voice messages is shown in figure 2.

,
равное пяти, следовательно, на пятый временной интервал функционирования Т₀₅, системы выделяется необходимое для передачи пяти запросов количество информационных каналов, а для передачи пакетов данных используются оставшиеся информационные каналы. Реальная же потребность системы в информационных каналах для передачи речевых сообщений на пятом временном интервале оказывается меньшей, так как за это время поступило всего три запроса. Аналогично производится прогноз и распределение ресурса информационных каналов для шестого и седьмого интервалов времени. Из приведенных на графике фиг.2 результатов видно, что выделяемого количества информационных каналов достаточно для речевых сообщений с заданным качеством, так как ресурса выделяется больше чем реальные потребности системы, т. е. пропускная способность системы используется неудовлетворительно. Однако следует заметить, что так будет не всегда. При дальнейшем возрастании количества запросов на передачу речевых сообщений использование указанного способа может привести к неоправданному ухудшению обслуживания запросов.From the graph presented in figure 2 it can be seen that the redistribution of the channel resource of the system occurs at equal time intervals for monitoring the process of receipt of voice requests T ₀ . At the same time, the number of information channels necessary for servicing N _{0i + 1} requests for transmitting voice messages equal to the previously predicted number of channels necessary for servicing N _{prog + 1} requests is allocated to the next time interval T _{0i + 1} . To calculate the number of N _{prog + 1} , an early recorded number of requests for information channels is used to ensure the transmission of voice messages at L time intervals. The number of time intervals L is selected from three to five. The larger the scatter in the number of queries, the greater should be the indicated number L. In most cases, a value of L equal to three is sufficient. In this example, it is assumed that the time interval T ₀ is equal to fifteen minutes, L is equal to three. As an example, we show how the calculation of the number of channels per fifth time interval T _{05 is} performed. To do this, find the sum of the values of the number of requests in the fourth N _s4 , third N _s3 and second N _s2 measurement interval, the obtained value is divided by the number L equal to three. Accordingly, we obtain

,
equal to five, therefore, for the fifth time interval of operation T _{05 of the} system, the number of information channels necessary for transmitting five requests is allocated, and the remaining information channels are used to transmit data packets. The real need of the system for information channels for transmitting voice messages in the fifth time interval is less, since only three requests were received during this time. Similarly, the forecast and distribution of the resource of information channels for the sixth and seventh time intervals are made. From the results shown in the graph of FIG. 2, it can be seen that the allocated number of information channels is sufficient for voice messages with a given quality, since the resource is allocated more than the real needs of the system, i.e., the system bandwidth is used unsatisfactorily. However, it should be noted that this will not always be the case. With a further increase in the number of requests for voice messages, the use of this method can lead to unjustified deterioration of service requests.

 Therefore, the approach is justified if the forecast estimates will be built with some margin, at the upper confidence limits. From the theory of mathematical statistics it is known that confidence limits for small samples are calculated using quantiles of the Student distribution.

 The considered values of the number of observation intervals are in the range from three to five, which is a small sample. To calculate the upper confidence limit of the indicated sample, it is necessary to set the required reliability coefficient N and determine the number of degrees of freedom, which, in accordance with the theory of mathematical statistics, should be one less than the sample size, i.e., L-1.

где

- целая часть числа, i=L+1, L+2, L+3,...The forecast of the number of applications for the transmission of voice messages is made according to the formula:

Where

is the integer part of the number, i = L + 1, L + 2, L + 3, ...

st _{H, n-1} is the quantile of the standardized Student distribution with a reliability coefficient H and (L -1) degree of freedom; S _L - the sum of the squares of the deviations of the measured and predicted values at L time intervals of measurement T ₀ . The above formula is described, for example, in the book of E.S. Wentzel. Probability theory. - M .: The main edition of the physical and mathematical literature, 1964, p. 324-327. The quantiles of the standardized Student distribution for a different number of degrees of freedom and reliability factors are known and presented in tabular form, for example, in the book of E.S. Wentzel. Probability theory. - M .: The main edition of the physical and mathematical literature, 1964, p. 568-569.

подставив значения указанных величин получим, что математическое ожидание количества заявок на восьмой интервал времени равно четырем. Второе слагаемое определяется следующим образом:

приняв коэффициент надежности равным 95%, получим, округлив до ближайшего целого, три заявки. Следовательно, на восьмой временной интервал необходимо выделить информационных каналов для передачи семи заявок речевых сообщений и оставшиеся каналы использовать для передачи пакетов данных. Реально N_з8 на восьмом временном интервале наблюдения Т₀₈ в соответствии с графиком фиг.2 составляет шесть запросов.The application of this method is shown in the graph of figure 2. Let us show the distribution of the resource using the upper confidence limit on the example of forecasting the number of requests for the eighth time interval T ₀₈ . In accordance with the above formula, the first term will be calculated as follows:

substituting the values of these quantities, we obtain that the mathematical expectation of the number of applications for the eighth time interval is four. The second term is defined as follows:

assuming a reliability factor of 95%, we get, rounding to the nearest integer, three bids. Therefore, for the eighth time interval, it is necessary to allocate information channels for transmitting seven voice message requests and use the remaining channels for transmitting data packets. Actually N _z8 on the eighth time interval of observation T ₀₈ in accordance with the schedule of figure 2 is six requests.

 For comparison, we give an example of the distribution of the bandwidth of a telecommunication system with multiple access, using the prototype method.

In this method, to determine the number of user requests, the last of the observations N _{s is used} . An example of such forecasting and the actual process of receiving requests for the transmission of voice messages is shown in Fig.3. From the graph shown in figure 3 it can be seen that the redistribution of the channel resource of the system occurs at equal intervals of time monitoring the process of receipt of voice requests T ₀ . In this case, the number of information channels necessary for transmitting N _{0i + 1} requests for voice messages equal to the number of requests N _Зi received in the previous observation interval is allocated to the next time interval T _{0i + 1} , and the remaining part of the channel resource is used to transmit data packets.

So for the fifth time interval T ₀₅ , for the transmission of voice messages, the number of information channels necessary for servicing N ₀₅ requests equal to N _s4 received during the fourth time interval T _{04 is allocated} . In the considered case, the allocated number of information channels is more than sufficient to ensure the transmission of voice information with the required quality, since a smaller number of information channels are required to service voice messages received during the fifth time interval T ₀₅ . It was selected from the calculation that eight requests for voice messages will be received and the remaining channels will be used to transmit data packets, but in reality for the specified time three requests for voice messages were received. With a slow increase in requests for voice messages, the system will constantly allocate a smaller amount of information channel resources for voice messages, as a result of which the quality of customer service will deteriorate, and with a slow decrease, there will always be an excess of allocated channels.

This fact can be illustrated by the example of the allocation of the channel resource for transmitting voice messages on the sixth time interval T ₀₆ . In accordance with the above principle, for the sixth time interval T _06, it is necessary to allocate the number of information channels necessary for transmitting N ₀₆ requests for voice messages, equal to N _s5 - the number necessary for servicing voice messages received during the fifth time interval T ₀₅ (three requests ), and use the remaining channels to transmit data packets. In fact, during the sixth interval T ₀₆ , four requests were received instead of the expected three, which would lead to a denial of service for part of the voice messages.

 Implementation of the proposed method in modern telecommunication systems does not seem to be a technically difficult task, since most modern control systems for such networks are built on the basis of computer technology with specialized software.

Claims (3)

1. The method of dynamic allocation of resources in a telecommunication system with multiple access, which consists in pre-allocating a portion of the total system resource for servicing N ₀ requests for voice messages, where N ₀ <N _max , N _max is the maximum number of requests for transmission of voice messages by the system, and the rest of the total system resource is allocated for transmission of data packets, measured in a given interval T _{0 the} number of incoming requests N ₃ for the transmission of voice messages, compare the number of received missing N ₃ and predefined requests N ₀ , the results of which redistribute the total resource of the system for transmitting voice messages and data packets, characterized in that the number of requests for sending voice messages is measured at L time intervals T ₀ , after which they are predicted for the next time period T _{0 the} number of possible requests N _prog for the transmission of voice messages, which is compared with a predetermined number of requests N ₀ and when the condition N ₀ <N _prog <N _max for the next time interval of the systems You allocate the part of the resource necessary for servicing N _prog requests, and the remaining part for transmitting data packets, and in the case of N _prog ≥N _{max, the} entire system resource is allocated for servicing requests for voice messages. 2. The method of claim 1, characterized in that the number L of time intervals T ₀ choose from three to five. 3. The method of claim 1 or 2, characterized in that predicting the number of possible requests for transmitting voice messages N _prog for the i-th time interval T ₀ , where i = L + 1, L + 2, L + 3, ... calculated by the formula

or according to the formula

Where

- the integer part of number; st _{H, n-1} is the quantile of the standardized Student distribution with a reliability coefficient H and (L-1) degree of freedom; S _L - the sum of the squares of the deviations of the measured and predicted values on L time intervals.

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