RU2183840C2 - Method and device for control over data transmission over radio channel - Google Patents

Abstract

FIELD: radio engineering, transmission of discrete messages. SUBSTANCE: invention can be employed to raise efficiency of use of carrying capacity of radio communication lines and networks, specifically, communication lines and systems of automatic dependent observation when data transmission complex is used in them. Technical result of invention consists in increase of utilization factor of carrying capacity of radio channel with irregular traffic as well as provision for zero dependence of average time of delivery of data packages with change in number of subscribers of radio network in wide limits. Technical result is achieved by transmission of data packages over radio channel in correspondence with protocol ALOHA in synchronous and asynchronous variants and intensity of formation of data packages and/or power of transmission of data packages are chosen depending on navigation data. EFFECT: raised efficiency of use of carrying capacity of radio communication lines and networks. 2 cl, 1 dwg

Description

 The invention relates to the field of radio engineering, namely to the field of transmission of discrete messages. The proposed technical solution can be used to increase the efficiency of using the bandwidth of radio communication lines and networks, in particular communication lines and networks in automatic dependent observation systems (ADS) when using a complex of technical data transmission equipment on these lines.

 The closest analogue (prototype) to the claimed technical solution in terms of the method is a method for controlling data transmission over a radio channel, including receiving navigation data, generating and transmitting data packets through at least one radio channel (US 5798726 A, 03.02.95).

 A prototype of the claimed technical solution in terms of the device is a radio data transmission control device including a navigation data source, the output of which is connected to the input of the data packetizer, and two outputs of the data packetizer are connected to the first and second inputs of the transmitter, and a data packet decoder, input which is associated with the output of the receiver (US 5798726 A, 03/03/95).

 The disadvantages of the known technical solution in terms of the method and device are the inefficient use of the bandwidth of the radio channel with uneven traffic, as well as the dependence of the average delivery time of data packets on the number of subscribers of the radio network, which when the radio network of the ADS system will reduce the accuracy of tracking subscribers.

 The objective of the invention is to develop a method and device for controlling data transmission over a radio channel, ensuring the achievement of a technical result, which consists in increasing the utilization rate of the radio channel throughput with uneven traffic, as well as in the absence of a dependence of the average delivery time of data packets when changing the number of radio network subscribers over a wide range, which when the radio network of the AZN system is operating, it ensures a fixed accuracy of subscribers tracking.

 The task in part of the proposed method is achieved by the fact that in the known method of controlling data transmission over a radio channel, including receiving navigation data, generating and transmitting data packets through at least one radio channel, data packets are transmitted in accordance with the ALOHA protocol in synchronous or non-synchronous versions and the intensity of the formation of data packets and / or the transmission power of data packets is selected depending on the navigation data.

 The task in part of the proposed device is achieved by the fact that in the known device for transmitting data via a radio channel containing a navigation data source, the output of which is connected to the input of the data packetizer, and two outputs of the data packetizer are connected to the first and second inputs of the transmitter, and a packet decoder the data input of which is connected to the output of the receiver, an ALOHA protocol controller, a data packet intensity control unit and / or a power control unit are additionally introduced transmission of data packets, and the first input of the ALOHA protocol controller is connected to the output of the navigation data source through the data packet intensity control unit, if available, and the additional transmitter input is connected to the output of the navigation data source through the data packet transmission power control unit, if available, output the packet decoder is connected to the second input of the ALOHA protocol controller, the output of which is connected to the control input of the packetizer.

 Due to the new set of essential features regarding the method and device for controlling data transmission over a radio channel, in contrast to the prototype, the coefficient of utilization of the radio channel throughput with uneven traffic increases, and there is no dependence of the average delivery time of data packets when the number of radio network subscribers changes over a wide range, which when working the radio network of the AZN system leads to a fixed accuracy of tracking subscribers.

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

 The inventive method and device for controlling data transmission over a radio channel are illustrated in the drawing, which shows a block diagram containing a navigation data source 1, an ALOHA protocol controller 2, a data packet generator 3, a transmitter 4, a data packet forming intensity control unit 5, a packet transmission power control unit 6, receiver 7 and data packet decoder 8. There may be either a data packet intensity control unit 5 or a packet transmission power control unit 6 or both blocks at the same time. The output of the navigation data source 1 is connected to the input of the data packetizer 3, the two outputs of which are connected to the first and second inputs of the transmitter 4, The first input of the ALOHA 2 protocol controller is connected to the output of the navigation data source 1 through the data packet intensity control unit 5, if any. The second input of the ALOHA 2 protocol controller is connected to the output of the data packet decoder 8, the input of which is connected to the output of the receiver 7. The output of the ALOHA 2 protocol controller is connected to the control input of the data packetizer 3. An additional input of the transmitter 4 is connected to the output of the navigation data source 1 through the control unit transmission power of data packets 6, if available.

 A description of the operation of the device and a specific example of the implementation of the method. The controller of the ALOHA 2 protocol at random times, based on the intensity of the formation of the data packets specified by the control unit for generating data packets 5, generates a permission signal for generating the data packet received by the data packetizer 3. A data packet containing navigation data received by the data packetizer 3 from a navigation data source 1, for example, a receiver of a GLONASS or NAVSTAR satellite radio navigation system, and / or data received by a packetizer data 3 with data input comes from the former three packets of data to the transmitter 4 and transmitted at a predetermined frame packet transmission power control data 6 to the control point. The ALOHA 2 protocol controller allows the formation and subsequent transmission of data packets to subscribers at any time of their choice. In the event of a collision of two or more data packets recorded in a downstream (control center - mobile subscriber) communication line, a decision is made about a conflict and conflicting subscribers a retransmission is assigned, and to reduce the likelihood of a re-conflict, the start of transmission is selected at a random time interval. To do this, the data packet received in the downlink is received from the receiver 7 to the decoder of the data packets 8, where a sign of a conflict occurs when the dispatch center receives the transmitted data packet from the data packet. This signal about the occurrence of a conflict enters the ALOHA 2 protocol controller, which retransmits the data packet until the sign of a conflict situation disappears.

S = Ge ^-2G , (1)
where S is the average throughput;
G - average traffic,
and for the synchronous version of the ALOHA protocol
S = Ge ^-G , (2)
moreover
G = λT, (3)
where λ is the intensity of the formation of data packets;
T is the duration of the transmission of each data packet;
(N. Abramson, The Throughput of Packet Broadcasting Channels, IEEE Transactions on Communications, Vol. COM-25, No. 1, January 1977, p. 118).

 Expressions (1) and (2) allow us to obtain a lower (pessimistic) value of the average data packet rate. In particular, one of the assumptions is the assumption of mutual destruction of conflicting data packets. At the same time, in radio engineering there is a capture phenomenon consisting in the selective reception of one of a group of signals simultaneously entering the input. In networks based on the transmission of data by simple signals, the capture phenomenon manifests itself in the successful reception of a signal whose power exceeds the total power of the remaining competing signals by the required value. If all network subscribers have the same transmitter power, then the signal power at the receiving point will monotonously decrease with increasing distance to the subscriber.

где G(r) - плотность распределения трафика (нормированный трафик с единицы площади расстояния r от точки приема);
S₀=G(0) - плотность трафика в точке приема;
r - расстояние до точки приема;
(N. Abramson, The Throughput of Packet Broadcasting Channels, IEEE Transactions on Communications, Vol. COM-25, No. 1, January 1977, p. 124). Таким образом, для обеспечения не зависящей от расстояния до точки приема плотности средней скорости необходимо изменять трафик в зависимости от этого расстояния. Аналогичное выражение для определения распределения плотности интенсивности формирования пакетов данных:

где L(r) - распределение плотности интенсивности формирования пакетов данных (полная интенсивность формирования пакетов данных с единицы площади расстояния r от точки приема).An expression is known for determining the traffic density for the case of perfect capture (for example, a frequency discriminator has this property) and a constant density of the average data packet rate

where G (r) is the traffic density (normalized traffic per unit area of distance r from the receiving point);
S ₀ = G (0) - traffic density at the receiving point;
r is the distance to the receiving point;
(N. Abramson, The Throughput of Packet Broadcasting Channels, IEEE Transactions on Communications, Vol. COM-25, No. 1, January 1977, p. 124). Thus, in order to ensure the average speed density independent of the distance to the receiving point, it is necessary to change the traffic depending on this distance. A similar expression for determining the distribution of the density density of the formation of data packets:

where L (r) is the distribution of the density density of the formation of data packets (the total intensity of the formation of data packets per unit area of the distance r from the receiving point).

 The independence of the average speed density from the distance from the subscriber to the receiving point provides the same average delivery time of data packets for subscribers located at any distance from the receiving point within the coverage area of the radio network. In relation to the radio network of the AZN system operating in accordance with the ALOHA multiple access protocol, this will mean that the accuracy of the subscriber’s tracking within the radio network coverage area will not depend on the distance from the subscriber to the receiving point.

 With a constant duration of the transmission of a data packet T, traffic control in a network with the ALOHA protocol can be carried out by changing the intensity of the formation of data packets depending on the distance from the subscriber to the receiving point. If the subscriber has a source of navigation data 1 that determines the location of the subscriber, and with known coordinates of the receiving point, this distance can easily be calculated.

 When subscribers are operating in radio shading conditions, for example, in development zones and / or rough terrain, the power at the receiving point (for the same transmit power of data packets) depends not only on the distance to the subscriber, but also on the shading conditions. To compensate for this dependence, it is necessary to control the transmission power of data packets depending on the location of the subscriber. The dependence of the transmission power of data packets on the location of the subscriber is chosen such that at the receiving point it decreases monotonically with increasing distance to the subscriber and does not depend on the azimuth of the subscriber. The location of the subscriber is again determined based on the navigation data received from the source of navigation data 1.

 In order to control the intensity of the formation of data packets and / or the transmission power of data packets depending on the location of the subscriber, the navigation data from the source of navigation data 1 is supplied to the control unit for the intensity of the formation of data packets 5 and / or to the control unit for the transmission power of data packets 6.

 The intensity of the formation of data packets in the control unit of the intensity of the formation of data packets 5 is selected so that the average delivery time of the data packet does not depend on the location of the subscriber, for example, guided by the following considerations.

 Let the system have a known number of n subscribers evenly distributed over a territory with a known area D. Then the average distribution density of subscribers (the number of subscribers per unit area) is n / D. Dividing by this value the value of the density of the formation of data packets, depending on the distance from the subscriber to the control center (5), we obtain the value of the intensity of the formation of data packets for the subscriber located at a distance r from the control center, coming from the control unit for the intensity of the formation of data packets 5 ALOHA protocol controller 2.

 The transmission power of data packets in the control unit of the transmission power of data packets 6 is selected, for example, so that at the receiving point it decreases monotonically with increasing distance to the subscriber and does not depend on the azimuth of the subscriber.

Claims (2)

 1. A method of controlling data transmission over a radio channel, including receiving navigation data, generating and transmitting data packets through at least one radio channel, characterized in that the transmission of data packets is carried out in accordance with the ALOHA protocol in synchronous or asynchronous versions, and the intensity of generating data packets and / or transmit power of the data packets is selected depending on the navigation data.  2. A control device for transmitting data via a radio channel, including a navigation data source, the output of which is connected to the input of the data packetizer, and two outputs of the data packetizer are connected to the first and second inputs of the transmitter, and a data packet decoder, the input of which is connected to the output of the receiver, characterized the fact that it is equipped with an ALOHA protocol controller, a data packet generation rate control unit and / or a data packet transmission power control unit, the first input of the channel controller ALOHA is connected to the output of the navigation data source through the control unit for the formation of data packets, if available, and the additional input of the transmitter is connected to the output of the navigation data source through the control unit for transmitting data packets if available, the output of the data packet decoder is connected to the second input of the protocol controller ALOHA, the output of which is connected to the control input of the data packetizer.