RU2013143215A - METHOD FOR FORMING DATA TRANSFER CHANNEL - Google Patents

Abstract

1. The method of forming a data transmission channel, which consists in the fact that at the first stage they search for all active transmitting and receiving devices (PUFs) of the transmitting side, determine the type of each PUF and its communication operator, assign an IP address to each identified active PUF with the formation of a communication channel; at the second stage, the data stream intended for transmission by means of a converter is converted to the internal format and divided into packets, and, if necessary, into packet segments, the finished packets are placed in the input buffer; at the third stage, the data from the input buffer is distributed over the active PUs of the transmitting side and sent to the receiving side, at the fourth stage, receiving data packets is received at the receiving side, and then the data is converted from the internal to the original format using a converter; characterized in that at the first stage, for each control unit, a set of individual settings is set that is necessary for its optimal operation, including network connection parameters and acceptable parameters for communication quality, and create a terminal device (OS) into which the mentioned individual settings and the assigned IP address of the corresponding PPU, terminal devices are interconnected by a switch of terminal devices; at the third stage, the data is transferred from the input buffer to the transmitting stream analyzer, which analyzes the transmitted data and logically separates the data into interaction flows, determined by the set of parameters of the sender, receiver, and type of interaction protocol, while the stream analyzer sets the processing mode for each of the transmitted packets and required

Claims (12)

1. The method of forming a data transmission channel, which consists in the fact that at the first stage they search for all active transmitting and receiving devices (PUFs) of the transmitting side, determine the type of each PUF and its communication operator, assign an IP address to each identified active PUF with the formation of a communication channel; at the second stage, the data stream intended for transmission by means of a converter is converted to the internal format and divided into packets, and, if necessary, into packet segments, the finished packets are placed in the input buffer; at the third stage, the data from the input buffer is distributed over the active PUs of the transmitting side and sent to the receiving side, at the fourth stage, receiving data packets is received at the receiving side, and then the data is converted from the internal to the original format using a converter; characterized in that at the first stage, for each control unit, a set of individual settings is set that is necessary for its optimal operation, including network connection parameters and acceptable parameters for communication quality, and create a terminal device (OS) into which the mentioned individual settings and the assigned IP address of the corresponding PPU, terminal devices are interconnected by a switch of terminal devices; at the third stage, the data is transferred from the input buffer to the transmitting stream analyzer, which analyzes the transmitted data and logically separates the data into interaction flows, determined by the set of parameters of the sender, receiver, and type of interaction protocol, while the stream analyzer sets the processing mode for each of the transmitted packets and requirements for the quality of transmission, then separately for each of the interaction flows, by means of a numbering device, sequentially assign numbers to data packets, and so the same numbers, if any, to the packet segments, after which the data packets are sent to the DT switch, by means of which each of the packets is assigned the identifier of the forwarding terminal device (DT), and thus, the packets are distributed according to the corresponding control points; in addition, by means of the generator of control packets of the transmitting side, a control packet is generated and transmitted to the switch of the terminal devices, by means of which the said control packet is sent through all available communication channels to the receiving side; in the fourth step, on the receiving side, by means of a decapsulator, the received stream is divided into control packets and data packets, the control packets being sent to the receiving packet control processor, and the data packets being sent to the receiving flow analyzer; by means of the control packet processor of the receiving side, for each communication channel, measurements and calculation of communication quality parameters are performed; by means of the control packet generator of the receiving side, regardless of the receipt of the control packet from the transmitting side, a counter control packet is formed in which information about the communication quality parameters of each communication channel is placed and the counter control packet is sent to the transmitting side; at the fifth stage, after receiving at least one counter control packet by the control packet control processor of the transmitting side, information about the communication quality parameters of each communication channel is extracted and the information is transmitted through the transmitting packet control packet generator to the op-amp switch; at the last, the information is updated taking into account the received information according to the parameters of the quality of communication of each of the communication channels and record these parameters in the corresponding OS; then, using the switch of the terminal devices, the data packets intended for sending are redistributed taking into account changes in the communication quality parameters of each communication channel; at the same time, communication channels that do not meet the conditions of the specified parameters of communication quality are excluded from the distribution; after a specified period of time after sending the previous control packet, the next control packet is formed on the control packet generator of the transmitting side; on the flow analyzer of the receiving side, the analysis of the received data is carried out and the data are logically divided into interaction flows, after which the interaction flows are sent to the sorter, which organizes the received packets, and sends the ordered packets to the collector, where they are glued segmented packets, if any, after which data packets are transmitted to a converter, by means of which the original data stream is restored; thus form a single high-speed data channel. 2. The method of forming a data transmission channel according to claim 1, characterized in that in the fifth step, when organizing data packets, the sorter sends concurrently through all communication channels the receipt of data packets to the numbering of the transmitting side, from where the lost data packets are re-sent to the receiving side, in addition, if a duplicate packet is received on the receiving side, it is deleted by the sorter in the process of organizing the received data packets. 3. The method of forming a data transmission channel according to claim 1, characterized in that in the fifth stage, for each communication channel, overclocking is performed in order to increase its throughput by transmitting more data packets per unit time than can be transmitted at the estimated speed obtained from control packet for this communication channel. 4. The method of forming a data transmission channel according to claims 1 to 3, characterized in that at the fifth stage, for each communication channel, bandwidth is backed up, maintaining the gained speed, by transmitting as many data packets per unit of time that can be transmitted at the estimated speed obtained from the control packet for this communication channel, and to ensure the availability of a sufficient number of data packets duplicate data packets intended for transmission. 5. The method of forming a data transmission channel according to claim 1, characterized in that an LTE modem is used as one of the control panels. 6. The method of forming a data transmission channel according to claim 1, characterized in that a GSM modem is used as one of the control panels. 7. The method of forming a data transmission channel according to claim 1, characterized in that a CDMA modem is used as one of the controllers. 8. The method of forming a data transmission channel according to claim 1, characterized in that a WIFI module is used as one of the control panels. 9. The method of forming a data transmission channel according to claim 1, characterized in that a satellite modem is used as one of the controllers. 10. The method of forming a data transmission channel according to claim 1, characterized in that an optical modem is used as one of the controllers. 11. The method of forming a data transmission channel according to claim 1, characterized in that an ADSL modem is used as one of the controllers. 12. The method of forming a data transmission channel according to claim 1, characterized in that an Ethernet modem is used as one of the controllers.