CN111194053B

CN111194053B - Electronic equipment for data transmission and implementation method thereof

Info

Publication number: CN111194053B
Application number: CN201911281264.8A
Authority: CN
Inventors: 吴云; 夏侯淑琴
Original assignee: Individual
Current assignee: Topronin Beijing Education Technology Co ltd
Priority date: 2019-12-13
Filing date: 2019-12-13
Publication date: 2021-03-05
Anticipated expiration: 2039-12-13
Also published as: CN111194053A

Abstract

The invention provides electronic equipment for data transmission and an implementation method thereof, wherein a three-order adjacent margin of a local self-organizing network node is extracted, then characteristic values are collected according to a first request and the state attribute of the local Adhoc network node, a data propagation label is introduced, block combination is carried out according to the label, the normalized characteristic values and load data are sent in a combined mode, and other signaling data are sent by utilizing an independent reliable channel, so that when the electronic equipment at a sending end is connected with a downlink self-organizing network, data structure self-consistency can be carried out according to the network node characteristic of the self-organizing network, data fusion is carried out according to specific load data and network characteristic, the load data and the network characteristic data are subjected to binary stripping, data sending and transmission are carried out according to the label, and the reliability of data transmission is improved.

Description

Electronic equipment for data transmission and implementation method thereof

Technical Field

The invention belongs to the field of electronic equipment, and particularly relates to electronic equipment for data transmission and an implementation method thereof.

Background

A data block is a group of several records arranged consecutively in order, and is a unit of data transferred between the main memory and the input/output device or the external memory. There are 3 ways of correspondence between physical records of data and logical records of data (data units that are logically linked and occupy a set of contiguous cells on a memory): one block is a record; one block contains a plurality of logical records; ③ one logical record occupies several blocks. The size of the data blocks may be fixed or variable, with gaps between blocks. The size of the data block is designed to be influenced by various factors, including input and output efficiency, storage space cost, computer application characteristics and the like.

In the data transmission process, data is generally required to be divided into blocks and transmitted according to a certain sequence order.

The general purpose of partitioning data at a certain granularity is to divide the data into small physical units, providing greater flexibility for operators and designers when managing the data. The small physical unit has the advantages of easy reconstruction, free indexing, sequential scanning, easy recombination, easy recovery, easy monitoring and the like. One of the essence of data warehouses is the flexible access to data, which is not achieved with large blocks of data.

In the development process of information technology, a plurality of network types are generated, wherein one network type which is commonly used at present and is based on the processing capability of the terminal electronic equipment is a local self-organizing network.

An Ad Hoc (Ad Hoc) network is a multi-hop temporary autonomous system, and its prototype is an ALOHA network established early in 1968 in the united states and a pr (packet radio) network proposed later in 1973. The ALOHA network requires a fixed base station, and each node in the network must be directly connected with all other nodes to communicate with each other, so that the ALOHA network is a single-hop network. Until PR networks, a true multi-hop network has not emerged, where the nodes do not need to be directly connected, but rather can relay information between two nodes that are far away and unable to communicate directly. PR networks are widely used in the military. IEEE has proposed to rename PR networks to Ad Hoc networks, which are today commonly referred to as mobile Ad Hoc networks, in developing the 802.11 standard.

A mobile ad hoc network. On one hand, the network information exchange adopts a packet switching mechanism in a computer network instead of a circuit switching mechanism in a telephone switching network; on the other hand, the user terminal is a portable terminal that can be moved, such as a notebook, a PDA, etc., and the user can be in a moving or stationary state at any time. Each user terminal in the wireless ad hoc network has the functions of a router and a host. As a host, the terminal can run various user-oriented applications; as a router, a terminal needs to run a corresponding routing protocol, and the distributed control and centerless network structure can maintain the residual communication capability after a part of communication networks are damaged, and has strong robustness and survivability.

As a distributed network, a mobile ad hoc network is an autonomous, multi-hop network, and the whole network has no fixed infrastructure, and can provide mutual communication between terminals under the condition that the existing network infrastructure (such as a base station and an AP) cannot be utilized or is inconvenient to utilize, but the external communication usually needs to be performed by a central node, or can be performed by a central node or a management node. Due to the limited transmission power and wireless coverage of the terminals, two terminals at a longer distance must perform packet forwarding by means of other nodes if communication is to be performed, so that a wireless multi-hop network is formed between the nodes.

The mobile terminals in the network have routing and packet forwarding functions and can form any network topology through wireless connection. The mobile ad hoc network can be used as a single network to independently work, and can also be accessed to the existing network in the form of an end subnet, such as an Internet network and a cellular network.

Often, a local transmitting end may be connected to various types of networks, for example, in a typical 3GPP mobile communication scenario, each AP serving as a transmitting end may be connected to a local mobile communication sub-network, and an access device serving as the sub-network performs uplink transmission and downlink feedback in a unified manner; furthermore, in the ad hoc network, the local sending end may serve as the only or a very small number of external transmission access points of the ad hoc network, and is configured to manage the local ad hoc network, control uplink data transmission and signaling transmission of each subordinate node, receive feedback from the server, and send the feedback to each managed local ad hoc network node in a downlink manner.

The invention provides an electronic device for data transmission and an implementation method thereof, wherein a data transmission label is introduced, and block combination is carried out according to the label; secondly, considering transmission of network characteristics of the self-organizing network, so that local Adhoc network nodes such as characteristics of weight, margin and the like are transmitted to a receiving end together, and the receiving end performs adaptive transmission by considering node characteristics during downlink feedback; thirdly, the invention introduces a binary relay structure, binary stripping is carried out on the load data and the network characteristic data, and data transmission is carried out through different relay servers which mutually correspond, so that the local adaptability and reliability of the electronic equipment for data transmission are ensured; fourthly, the invention introduces a unique margin server and sends a first request to the margin server, extracts a local self-organizing network node three-order adjacent margin table, determines the network three-order/second-order/single-order adjacent weight, is clear and accurate, and remarkably and further embodies the consistency of the self-organizing network node in the network, namely the communication popularity and the transmission margin compared with the prior art; and fifthly, orderly controlling data blocking and fusion by using the propagation label.

Disclosure of Invention

The present invention is directed to an electronic device for data transmission and a transmission method thereof that are superior to the related art.

In order to achieve the purpose, the technical scheme of the invention is as follows:

an electronic device for data transmission, the electronic device comprising:

a local sender, wherein,

the local transmitter is to:

sending a first request to a margin server connected with a sending end, extracting a local self-organizing network node third-order proximity margin table, wherein the local self-organizing network node third-order proximity margin table is stored in the margin server connected with the sending end, and the local self-organizing network node proximity margin table is characterized in that: firstly, the importance degree of each node in the local self-organizing network in wireless communication for a direct adjacent node, a primary-hop indirect connection node and a secondary-hop indirect connection node in the network, and secondly, the communication margin under the condition that the processing capacity of each node is consistent;

the first local self-organizing network collector is used for implementing first local self-organizing network collection, extracting a first network characteristic value set from each self-organizing node of a local self-organizing network under the sending end, and carrying out sequential XOR operation between adjacent elements on the first network characteristic value set to obtain a first network characteristic collection value;

a second local self-organizing network aggregator, which performs aggregation of a second local self-organizing network, extracts a second network characteristic value of each node from the extracted three-order adjacent allowance table of the local self-organizing network nodes by using a local analyzer in the local transmitter, aggregates the second network characteristic values according to numbers preset by the nodes in the self-organizing network, and performs sequential exclusive-or operation between adjacent elements on the aggregated second network characteristic value set to obtain a second network characteristic aggregation value;

a load data slicer, which is used for partitioning the actual load data by using the load data slicer in the local transmitter, specifically for partitioning the load data in the data subframe by using a data partitioning algorithm based on label propagation;

the double-relay structure is used for receiving signaling and data sent by a mobile communication sending end, and comprises the following components:

the first relay server is used for receiving a first standard data structure sent by a local sender at a mobile communication sending end in an uplink manner, wherein the first standard data structure is a first data structure formed by randomly inserting and combining a first network characteristic value and a block with a label binary tail bit of 0 of load data in a single data subframe load part, recording the combination sequence of the first network characteristic value and the block with the label binary tail bit of 0 of the load data in the single data subframe load part, supplementing a serial number representing the combination sequence of the block with the label binary tail bit of 0 of the load data in the single data subframe load part into the tail part of a propagation label, establishing a separate propagation label for the first network characteristic value and attaching to the first network characteristic value;

a second relay server, configured to receive a second standard data structure sent by a local sender at a mobile communication sending end in an uplink manner, where the second standard data structure is a second data structure in which a second network characteristic value and a block with a label binarization end bit of 1 in a single data subframe load portion of load data are arbitrarily inserted and combined, and record a combination sequence of the second network characteristic value and the block with the label binarization end bit of 1 in the single data subframe load portion of the load data, and supplement a sequence number representing the combination sequence of the blocks with the label binarization end bit of 1 in the single data subframe load portion of the load data into a tail of a propagation label, and establish a separate propagation label for the second network characteristic value, where the sequence number is attached to the second network characteristic value;

a data tag memory responsible for writing tags and storing data tags for corresponding data blocks; wherein the label at least comprises the following four parts:

a binary group of tokens; third-order neighbor information;

the direct neighbor information, and,

a combined serial number;

a transmit data normalizer for data transmit normalization using the transmit data normalizer in the local sender:

creating an uplink first transmission path from the downlink ad-hoc network path to the first relay server using a transmit function msg _ trans1_ normalization, transmitting a first standard data structure to the first relay server through the first transmission path, wherein the transmit function msg _ trans1_ normalization comprises:

the first mobile communication connection function is used for realizing the communication with the native socket function; the first memory head searching function is used for searching a sending destination address in local first sending service and sending load data to the destination address through the first destination sending function;

creating an uplink second transmission path from the downlink ad-hoc network path to the second relay server using a transmit function msg _ trans2_ normalization, and transmitting a second standard data structure to the second relay server through the second transmission path, wherein the transmit function msg _ trans2_ normalization includes:

the second mobile communication connection function is used for realizing the communication with the original socket function; the second memory head searching function is used for searching a sending destination address in the local second sending service and sending load data to the destination address through the second destination sending function;

and the independent signaling transmission mechanism transmits other signaling information except the first network characteristic value and the second network characteristic value through a single reliable channel.

Preferably, the apparatus further includes a first network feature set value calculator, configured to perform a sequential xor operation between adjacent elements on the first network feature set to obtain a first network feature set value, and specifically includes:

first, a feature value set { a }is selected₁，a₂，a₃，……a_n1 st element a₁And a second element a₂Binarizing and carrying out XOR operation to obtain an operation result b₁Then b is₁And the next successive element a of the feature value set₃After binarization, the result is processed by XOR operation to obtain operation result b₂And so on until the feature value set { a }₁，a₂，a₃，……a_nAll elements of the network are involved in calculation to obtain a first network characteristic aggregation value b_n-1And n is the number of self-organizing nodes of the local self-organizing network.

Preferably, in the device, the first network characteristic value is a normalized channel effective interference radius mean value of each node.

Preferably, the device comprises a second network characteristic value first calculator for calculating the second network characteristic value through the weight sum of each node, which is prestored in the third-order adjacent allowance table of the local self-organizing network node, of each directly adjacent node of the node, but not the node itself.

Preferably, the apparatus further comprises a second network characteristic value calculator, configured to calculate the second network characteristic value by using a sum of weights of each node in direct vicinity of the node, a node in direct vicinity of the node, and the node itself, which are pre-stored in a third-order vicinity allowance table of the local ad hoc network node.

Preferably, the apparatus further includes a second network feature set value calculator, configured to perform a sequential xor operation between adjacent elements on the second network feature value set to obtain a second network feature set value, and specifically includes:

first, a second network feature value set { c }is selected₁，c₂，c₃，……c_n1 st element a₁And a second element c₂Binarizing and carrying out XOR operation to obtain an operation result d₁Then d is added₁And the next continuation element c of the feature value set₃After the dualization, the result is subjected to exclusive OR operation to obtain an operation result d₂And so on until the feature value set { c }₁，c₂，c₃，……c_nAll elements of the network are involved in calculation to obtain a first network feature aggregation value d_n-1And n is the number of self-organizing nodes of the local self-organizing network.

In addition, the invention provides an electronic device implementing method for data transmission, comprising the following steps:

s102, establishing a local transmitter at a transmitting end, wherein the local transmitter comprises the following operation steps:

s104, sending a first request to a margin server connected with a sending end, extracting a local self-organized network node three-order proximity margin table, wherein the local self-organized network node three-order proximity margin table is stored in the margin server connected with the sending end, and the local self-organized network node proximity margin table is characterized in that: firstly, the importance degree of each node in the local self-organizing network in wireless communication for a direct adjacent node, a primary-hop indirect connection node and a secondary-hop indirect connection node in the network, and secondly, the communication margin under the condition that the processing capacity of each node is consistent;

s106: the method comprises the steps that a first local self-organizing network is collected, each self-organizing node of a local self-organizing network under a sending end is subjected to first network characteristic value set extraction, and the first network characteristic value set is subjected to sequential XOR operation between adjacent elements to obtain a first network characteristic collection value;

s108: collecting the second local self-organizing network, extracting the second network characteristic value of each node from the extracted three-order adjacent allowance of the local self-organizing network nodes by using a local analyzer in the local transmitter, collecting the second network characteristic value according to the preset number of the node in the self-organizing network, and carrying out sequential XOR operation on adjacent elements on the collected second network characteristic value set to obtain a second network characteristic collection value;

s110: partitioning actual load data by using a load data slicer in the local transmitter, specifically, partitioning the load data in a data subframe by using a data partitioning algorithm based on label propagation;

s112: constructing a double-relay structure for receiving signaling and data sent by a mobile communication sending end, wherein the double-relay structure comprises the following components:

and updating the propagation label, including writing the label for the corresponding data block and storing the propagation label. Wherein, the label at least comprises the following four parts:

a binary group of tokens; third-order neighbor information;

the direct neighbor information, and,

a combined serial number;

s114: performing data transmission normalization using a transmission data normalizer in the local transmitter:

s118: transmitting other signaling information than the first network characteristic value and the second network characteristic value through a separate reliable channel.

Preferably, the method of performing a sequential xor operation between adjacent elements on the first network feature value set to obtain a first network feature set value specifically includes:

Preferably, in the method, the first network characteristic value is a normalized channel effective interference radius mean value of each node.

Preferably, in the method, the second network characteristic value is a sum of weights of each node, which is pre-stored in a third-order proximity allowance table of the local ad hoc network node, of each directly neighboring node of the node, but not of the node itself.

Preferably, in the method, the second network characteristic value is a sum of weights of each directly neighboring node of each node, a directly neighboring node of the directly neighboring node, and the node itself, which are pre-stored in a third-order neighboring allowance table of the local ad hoc network node by each node.

Preferably, the method of performing a sequential xor operation between adjacent elements on the second network feature value set to obtain a second network feature set value specifically includes: first, a second network feature value set { c }is selected₁，c₂，c₃，……c_n1 st element a₁And a second element c₂Binarizing and carrying out XOR operation to obtain an operation result d₁Then d is added₁And the next continuation element c of the feature value set₃After binarization, the result is processed by XOR operation to obtain operation result d₂And so on until the feature value set { c }₁，c₂，c₃，……c_nAll elements of the network are involved in calculation to obtain a first network characteristic aggregation value d_n-1And n is the number of self-organizing nodes of the local self-organizing network.

The invention provides electronic equipment for data transmission and an implementation method thereof. In the process of processing the uplink transmission process of the local self-organizing network, a margin server and a binary relay server are introduced to be matched to finish the structural normalization of the local transmitter, and the transmission load data of each node is fused with the margin and the weight of the node and is combined and transmitted through a unique binary relay structure. Through the electronic equipment for data transmission and the implementation method thereof, firstly, a normalized structure that the local transmitter controls the sending data is introduced, and a more standardized processing result than the existing uplink processing is obtained; secondly, considering transmission of network characteristics of the self-organizing network, so that local Adhoc network nodes such as characteristics of weight, margin and the like are transmitted to a receiving end together, and the receiving end performs adaptive transmission by considering node characteristics during downlink feedback; thirdly, the invention introduces a binary relay structure, binary stripping is carried out on the load data and the network characteristic data, and data transmission is carried out through different relay servers which mutually correspond, so that the local adaptability and reliability of the electronic equipment for data transmission are ensured; fourthly, the invention introduces a unique margin server and sends a first request to the margin server to extract the three-order adjacent margin table of the local self-organizing network node and determine the three-order/second-order/single-order adjacent weight of the network, thereby being clear and accurate, obviously reflecting the consistency of the self-organizing network node in the network, namely the communication popularity and the transmission margin compared with the prior art, and simultaneously leading the block combination of the load data and the network characteristic value data to be controllable through a data propagation label.

Drawings

FIG. 1 is a primary block diagram of one embodiment of an electronic device shown in the present invention;

FIG. 2 is a basic block diagram illustrating one embodiment of an electronic device implementing a method for data transmission in accordance with the present invention;

FIG. 3 is an example of a structure of a transmit function msg _ trans1_ normalization according to one embodiment of the present invention;

fig. 4 is an example of a structure of a transmit function msg _ trans2_ normalization according to an embodiment of the present invention.

Fig. 5 is an example of a propagation tag infrastructure showing one embodiment of an electronic device implemented method for data transmission of the present invention.

Detailed Description

The following detailed description is directed to several embodiments and advantageous effects of an electronic device for data transmission and a method thereof, which are intended to facilitate a more thorough examination and breakdown of the invention.

For better understanding of the technical solutions of the present invention, the following detailed descriptions of the embodiments of the present invention are provided with reference to the accompanying drawings.

It should be understood that the described embodiments are only some embodiments of the invention, and not all embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

The terminology used in the embodiments of the invention is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. As used in the examples of the present invention and the appended claims, the singular forms "a," "an," and "the" are intended to include the plural forms as well, unless the context clearly indicates otherwise.

It should be understood that the term "and/or" as used herein is merely one type of association that describes an associated object, meaning that three relationships may exist, e.g., a and/or B may mean: a exists alone, A and B exist simultaneously, and B exists alone. In addition, the character "/" herein generally indicates that the former and latter related objects are in an "or" relationship.

It should be understood that although the terms first, second, etc. may be used in embodiments of the invention to describe methods and corresponding apparatus, these keywords should not be limited to these terms. These terms are only used to distinguish keywords from each other. For example, the first network characteristic value, the first local ad hoc network characteristic subset, the first local ad hoc network aggregator may also be referred to as a second network characteristic value, a second local ad hoc network characteristic subset, a second local ad hoc network aggregator, and similarly, the second network characteristic value, the second local ad hoc network characteristic subset, the second local ad hoc network aggregator may also be referred to as a first network characteristic value, a first local ad hoc network characteristic subset, a first local ad hoc network aggregator without departing from the scope of embodiments of the present invention.

The word "if" as used herein may be interpreted as "at … …" or "when … …" or "in response to a determination" or "in response to a detection", depending on the context. Similarly, the phrases "if determined" or "if detected (a stated condition or event)" may be interpreted as "when determined" or "in response to a determination" or "when detected (a stated condition or event)" or "in response to a detection (a stated condition or event)", depending on the context.

As shown in fig. 1, the electronic device for data transmission claimed in the present invention comprises:

a local sender, wherein,

the local transmitter is to:

a binary group of tokens; third-order neighbor information;

the direct neighbor information, and,

a combined serial number;

Therefore, as a preferred embodiment, the apparatus further includes a first network feature set value calculator, configured to perform a sequential xor operation between adjacent elements on the first network feature set to obtain a first network feature set value, and specifically includes:

As another preferred embodiment that can be superimposed, the insertion combination in the device may be performed by performing any sequential combination of the qualified individual load data blocks and the first/second network characteristic values (as individual load data blocks, according to a typical processing principle), to obtain combined total load data, and modifying the propagation label of each load data block according to the combined sequence of each load data block and the first/second network characteristic values (as individual load data blocks), supplementing the propagation label with its sequential serial number in the combined new total load data, and supplementing the propagation label with the first/second network characteristic values (as individual load data blocks), where the supplementary propagation label of the first/second network characteristic values (as individual load data blocks) is divided by the last bits into the first/second network characteristic values (as individual load data blocks) Payload data block) the preamble data bits are all set to zero outside the sequential sequence number in the combined new total payload data.

As a preferred embodiment, in the apparatus, the first network characteristic value is a normalized channel effective interference radius mean value of each node.

As a preferred embodiment, the apparatus includes a second network characteristic value first calculator for calculating the second network characteristic value by a weight sum of each node, which is pre-stored in a third-order proximity allowance table of the local ad hoc network node, of each directly neighboring node of the node, not the own node.

As another superimposable preferred embodiment, the apparatus further comprises a second network characteristic value second calculator for calculating the second network characteristic value by means of the sum of weights of each node in direct vicinity of the node, and direct vicinity nodes of the direct vicinity nodes and the node itself, which are pre-stored in a third order vicinity allowance table of the local ad hoc network node by each node.

As another preferred embodiment that can be superimposed, the apparatus further includes a second network feature set value calculator, configured to perform sequential xor operation between adjacent elements on the second network feature set to obtain a second network feature set value, and the method specifically includes:

Referring to fig. 2, the specification fig. 2 shows a basic block diagram of an embodiment of an electronic device for data transmission according to the present invention. The method comprises the following steps:

a binary group of tokens; third-order neighbor information;

the direct neighbor information, and,

a combined serial number;

As another preferred embodiment that can be superimposed, the method performs sequential xor operation between adjacent elements on the first network feature value set to obtain a first network feature set value specifically includes:

As another stackable preferred embodiment, in the method, the first network characteristic value is a normalized channel effective interference radius mean value of each node.

As another stackable preferred embodiment, the second network characteristic value in the method is a sum of weights of each node in each direct neighboring node of the node, the direct neighboring node of the direct neighboring node, and the node itself, which are pre-stored in a third-order neighboring margin table of the local ad hoc network node by each node.

As another preferred embodiment that can be superimposed, the method performs sequential xor operation between adjacent elements on the second network feature value set to obtain a second network feature set value specifically includes: first, a second network feature value set { c }is selected₁，c₂，c₃，……c_n1 st element a₁And a second element c₂Binarizing and carrying out XOR operation to obtain an operation result d₁Then d is added₁And the next successive element c of the feature value set₃After binarization, the result is processed by XOR operation to obtain operation result d₂And so on until the feature value set { c }₁，c₂，c₃，……c_nAll elements of the network are involved in calculation to obtain a first network characteristic aggregation value d_n-1And n is the number of self-organizing nodes of the local self-organizing network.

As another preferred embodiment that can be superimposed, the insertion combination in the device may be any sequence combination of the qualified load data blocks and the first/second network characteristic values (regarded as single load data blocks) to obtain the combined total load data, and modify the propagation label of each load data block according to the combination sequence of each load data block and the first/second network characteristic values (regarded as single load data blocks), and supplement the sequence serial number of each load data block in the combined new total load data after the label, and supplement the propagation label with the first/second network characteristic values (regarded as single load data blocks), where the supplement propagation label of the first/second network characteristic values (regarded as single load data blocks) is divided by the last bits into the first/second network characteristic values (regarded as single load data blocks) in the combination The bits of the preamble data are all set to zero outside the sequence number in the new total load data.

Description of the drawings fig. 3 is an example of a structure of a transmit function msg _ trans1_ normalization according to an embodiment of the present invention showing an electronic device implementing a method for data transmission;

referring to fig. 3, an uplink first transmission path from a downlink ad hoc network path to a first relay server is created using a transmit function msg _ trans1_ normalization, and a first standard data structure is transmitted to the first relay server through the first transmission path, wherein the transmit function msg _ trans1_ normalization comprises:

description of the drawings fig. 4 is an example of a structure of a transmit function msg _ trans2_ normalization according to an embodiment of the present invention showing an electronic device implementing a method for data transmission;

referring to fig. 4, an uplink second transmission path from the downlink ad hoc network path to the second relay server is created using a transmit function msg _ trans2_ normalization, and the second standard data structure is transmitted to the second relay server through the second transmission path, wherein the transmit function msg _ trans2_ normalization includes:

description of the drawings fig. 5 is a basic structural example of a propagation tag showing one embodiment of an electronic device implemented method for data transmission of the present invention, with known fields in some tags not shown or absent;

as can be seen with reference to fig. 4, the propagation tag is updated, including writing the tag for the corresponding data block and storing the propagation tag. Wherein the label at least comprises the following four parts:

a binary group of tokens; third-order neighbor information; direct neighbor information, and, a combined sequence number.

The invention provides an electronic device for data transmission and a transmission method thereof, a data transmission label is introduced and is coded, a local transmitter is established at a transmitting end, a first request is sent to a margin server connected with the transmitting end, three-order adjacent margin tables of local self-organization network nodes are extracted, then characteristic values are collected according to the first request sent to the margin server connected with the transmitting end and the state attribute of the local Adhoc network nodes, the normalized characteristic values and load data are combined and transmitted, other signaling data are sent by using a single reliable channel, so that when the electronic device at the transmitting end is connected with a downlink self-organization network, the data structure can be self-consistent according to the network node characteristic of the self-organization network, the data fusion is carried out according to the specific load data and the network characteristic, and a binary relay structure is introduced, the load data and the network characteristic data are subjected to binary stripping, and data transmission is carried out through different relay servers which correspond to each other, so that the local adaptability and reliability of data transmission of electronic equipment are guaranteed, the characteristics of local Adhoc network nodes such as weight, margin and the like can be simultaneously transmitted to a receiving end in consideration of the characteristics of the nodes for adaptive transmission by the receiving end in consideration of the characteristics of the nodes during downlink feedback, and meanwhile, a data transmission label is introduced and block combination is carried out according to the label.

In all the above embodiments, in order to meet the requirements of some special data transmission and read/write functions, the above method and its corresponding devices may add devices, modules, devices, hardware, pin connections or memory and processor differences to expand the functions during the operation process.

It is clear to those skilled in the art that, for convenience and brevity of description, the specific working processes of the above-described method, apparatus and unit may refer to the corresponding processes in the foregoing method embodiments, and are not described herein again.

In the embodiments provided in the present invention, it should be understood that the disclosed system, apparatus and method may be implemented in other ways. For example, the above-described apparatus embodiments are merely illustrative, and for example, the division of the method steps into only one logical or functional division may be implemented in practice in another manner, e.g., multiple units or components may be combined or integrated into another system, or some features may be omitted, or not implemented. In addition, the shown or discussed mutual coupling or direct coupling or communication connection may be an indirect coupling or communication connection through some interfaces, devices or units, and may be in an electrical, mechanical or other form.

The units described as individual steps of the method, apparatus separation parts may or may not be logically or physically separate, or may not be physical units, and may be located in one place, or may be distributed on a plurality of network units. Some or all of the units can be selected according to actual needs to achieve the purpose of the solution of the embodiment.

In addition, the method steps, the implementation thereof, and the functional units in the embodiments of the present invention may be integrated into one processing unit, or each unit may exist alone physically, or two or more units are integrated into one unit. The integrated unit can be realized in a form of hardware, or in a form of hardware plus a software functional unit.

The above-described method and apparatus may be implemented as an integrated unit in the form of a software functional unit, which may be stored in a computer readable storage medium. The software functional unit is stored in a storage medium and includes several instructions for causing a computer device (which may be a personal computer, a server, or a network device) or a Processor (Processor) to execute some steps of the methods according to the embodiments of the present invention. And the aforementioned storage medium includes: a U disk, a removable hard disk, a Read-Only Memory (ROM), a Random Access Memory (RAM), an NVRAM, a magnetic disk, or an optical disk, and various media capable of storing program codes.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents, improvements and the like made within the spirit and principles of the present invention are intended to be included within the scope of the present invention.

It should be noted that: the above embodiments are only used to explain and illustrate the technical solution of the present invention more clearly, and not to limit the same; although the present invention has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some technical features may be equivalently replaced; and the modifications or the substitutions do not make the essence of the corresponding technical solutions depart from the spirit and scope of the technical solutions of the embodiments of the present invention.

Claims

1. An electronic device for data transmission, the electronic device comprising:

a local sender, wherein,

the local transmitter is to:

sending a first request to a margin server connected with a sending end, and extracting a local self-organizing network node three-order proximity margin table, wherein the local self-organizing network node three-order proximity margin table is stored in the margin server connected with the sending end, and the local self-organizing network node three-order proximity margin table is characterized in that:

first, each node in the local ad hoc network has an importance degree in wireless communication for a direct adjacent node, a primary-hop indirect connection node, and a secondary-hop indirect connection node in the network, and

secondly, the communication margin under the condition that the processing capacity of each node is consistent;

the first local self-organizing network collector is used for implementing first local self-organizing network collection, extracting a first network characteristic value set from each self-organizing node of a local self-organizing network under a sending end, and carrying out sequential XOR operation between adjacent elements on the first network characteristic value set to obtain a first network characteristic collection value;

a second local self-organizing network aggregator, which performs aggregation of a second local self-organizing network, extracts a second network characteristic value of each node from the extracted three-order adjacent allowance tables of the nodes of the local self-organizing network by using a local analyzer in the local transmitter, aggregates the second network characteristic values according to numbers preset by the nodes in the self-organizing network, and performs sequential exclusive or operation between adjacent elements on the aggregated second network characteristic value set to obtain a second network characteristic aggregation value;

the first relay server is used for receiving a first standard data structure sent by a local sender of a mobile communication sending end in an uplink manner, wherein the first standard data structure is a first data structure formed by randomly inserting and combining a first network characteristic value and a block with a label binarization tail bit of 0 of load data in a single data subframe load part, recording the combination sequence of the first network characteristic value and the block with the label binarization tail bit of 0 of the load data in the single data subframe load part, supplementing a serial number representing the combination sequence of the block with the label binarization tail bit of 0 of the load data in the single data subframe load part into the tail part of a propagation label, establishing a separate propagation label for the first network characteristic value and attaching to the first network characteristic value;

a second relay server, configured to receive a second standard data structure sent by a local sender at a mobile communication sending end in an uplink manner, where the second standard data structure is a second data structure in which a second network characteristic value and a block with a label binarization end bit of 1 in a single data subframe load portion of load data are arbitrarily inserted and combined, and records a combination sequence of the second network characteristic value and the block with the label binarization end bit of 1 in the single data subframe load portion of the load data, and fills a sequence number representing the combination sequence of the blocks with the label binarization end bit of 1 in the single data subframe load portion of the load data into a tail of a propagation label, and establishes a separate propagation label for the second network characteristic value, where the sequence number is attached to the second network characteristic value;

first, a duplet of tokens;

second, third order neighbor information;

third, direct neighbor information, and,

fourth, the combined serial number;

creating an uplink first transmission channel from the downlink ad-hoc network channel to the first relay server using a transmit function msg _ trans1_ normalization, and transmitting a first standard data structure to the first relay server through the first transmission channel, wherein the transmit function msg _ trans1_ normalization comprises:

and creating an uplink second transmission channel from the downlink self-organizing network channel to the second relay server by using a transmit function msg _ trans2_ normalization, and transmitting a second standard data structure to the second relay server through the second transmission channel, wherein the transmit function msg _ trans2_ normalization comprises:

2. The electronic device of claim 1, wherein the device further comprises a first network feature set value calculator configured to perform a sequential exclusive-or operation between adjacent elements on the first network feature value set to obtain a first network feature set value, and specifically comprises:

3. The electronic device of claim 1, wherein the first network characteristic value is a normalized channel effective interference radius mean of each node; the equipment comprises a first calculator of a second network characteristic value, a second calculator of the second network characteristic value and a third calculator of the second network characteristic value, wherein the first calculator is used for calculating the second network characteristic value through the weight sum of each node, which is pre-stored in a third-order adjacent allowance table of the local self-organizing network node, of each node, and is not used for calculating the second network characteristic value of the node; the device also comprises a second network characteristic value second calculator, which is used for calculating the second network characteristic value through the weight sum of each node, each direct adjacent node of the node, the direct adjacent nodes of the direct adjacent nodes and the node itself, which are pre-stored in a third-order adjacent allowance table of the local self-organizing network node by each node.

4. The electronic device of claim 1, wherein the device further comprises a second network feature set value calculator configured to perform a sequential exclusive-or operation between adjacent elements on the second network feature value set to obtain a second network feature set value, and specifically comprises:

first, a second network feature value set { c }₁，c₂，c₃，……c_n1 st element c₁And a second element c₂Binarizing and carrying out XOR operation to obtain an operation result d₁Then d is added₁And the next continuation element c of the feature value set₃After binarization, the result is processed by XOR operation to obtain operation result d₂And so on until the feature value set { c }₁，c₂，c₃，……c_nAll elements of the network are involved in calculation to obtain a second network characteristic aggregation value d_n-1And n is the number of self-organizing nodes of the local self-organizing network.

5. An electronic device implemented method for data transmission, the method comprising:

firstly, a local transmitter is established at a transmitting end, wherein the local transmitter comprises the following operation steps:

secondly, sending a first request to a margin server connected with a sending end, and extracting a local self-organizing network node three-order proximity margin table, wherein the local self-organizing network node three-order proximity margin table is stored in the margin server connected with the sending end, and the local self-organizing network node three-order proximity margin table is characterized in that:

the third step: the method comprises the steps that a first local self-organizing network is collected, each self-organizing node of a local self-organizing network under a sending end is subjected to first network characteristic value set extraction, and the first network characteristic value set is subjected to sequential XOR operation between adjacent elements to obtain a first network characteristic collection value;

the fourth step: the second local self-organizing network is collected, a local analyzer in the local transmitter is used for extracting second network characteristic values of all the extracted third-order adjacent allowance tables of the local self-organizing network nodes, the collection is carried out according to preset numbers of the nodes in the self-organizing network, and the collected second network characteristic value sets are subjected to sequential XOR operation among adjacent elements to obtain second network characteristic collection values;

the fifth step: partitioning actual load data by using a load data slicer in the local transmitter, specifically, partitioning the load data in a data subframe by using a data partitioning algorithm based on label propagation;

and a sixth step: constructing a double-relay structure for receiving signaling and data sent by a mobile communication sending end, wherein the double-relay structure comprises the following components:

updating the propagation label, including writing the label for the corresponding data block and storing the propagation label; wherein the label at least comprises the following four parts:

a binary group of tokens; third-order neighbor information; direct neighbor information, and, a combined sequence number;

the seventh step: performing data transmission normalization using a transmission data normalizer in the local transmitter:

eighth step: transmitting other signaling information than the first network characteristic value and the second network characteristic value through separate reliable channels.

6. The method as claimed in claim 5, wherein the obtaining the first net feature set value by performing the exclusive-or operation between adjacent elements on the first net feature value set specifically comprises:

7. The electronic device implemented method of claim 6, wherein the first network characteristic value is a normalized channel effective interference radius mean of each node; in the method, the second network characteristic value is a weight sum of each node, which is pre-stored in a third-order adjacent allowance table of the local ad hoc network node, of each directly adjacent node of the node instead of the node.

8. The method as claimed in claim 7, wherein the second network characteristic value is a sum of weights of each node's respective immediately neighboring nodes and their immediate neighboring nodes and the node itself, which are pre-stored in a third-order proximity allowance table of the local ad hoc network node by each node.

9. The method as claimed in claim 7, wherein the obtaining the second network feature set value by performing a sequential xor operation between adjacent elements on the second network feature set specifically comprises:

10. An electronic communication system comprising a sender, a receiver, and a binary relay server, a signaling control server, and a margin server, wherein the sender comprises the electronic device of any of claims 1-4.