CN116170232B - Quantum gateway data display management system - Google Patents

Abstract

The invention discloses a quantum gateway data display management system, which relates to the technical field of data monitoring management and comprises a management center, wherein the management center is in communication connection with a data acquisition module, an embedded gateway module, a data processing module and a terminal display module; setting an acquisition queue through a data acquisition module to acquire data, and converting the acquired data into quantum state data; the embedded gateway module is provided with a partition processing unit, a dynamic stacking unit and a distribution pushing unit for partitioning operation, dynamic distribution gateway storage stack and channel distribution respectively; encrypting the split area quantum data through a data processing module, and generating dynamic data through dynamic marking change positions; the terminal display module is provided with two modes of portable mobile terminal display and fixed terminal display, and generates a data matrix according to dynamic data and carries out authority assessment, so that the purposes of gateway data display and management are realized.

Description

Quantum gateway data display management system

Technical Field

The invention relates to the technical field of data monitoring management, in particular to a quantum gateway data display management system.

Background

The traditional gateway data display system has the defects of insufficient data security, easiness in network attack and hacking invasion, frequent occurrence of data leakage is caused, in the data transmission process, the data is not provided with destruction time and corresponding state, the congestion phenomenon of transmission is caused, no reasonable authority assessment means are adopted in the management stage, corresponding measures are adopted, and the industrial enterprises adopting the gateway data display system cannot timely remove faults, so that the problems are all considered to be solved.

Disclosure of Invention

In order to solve the above problems, an object of the present invention is to provide a quantum gateway data display management system.

The aim of the invention can be achieved by the following technical scheme: the quantum gateway data display management system comprises a management center, wherein the management center is in communication connection with a data acquisition module, an embedded gateway module, a data processing module and a terminal display module;

the data acquisition module acquires data parameters by arranging a plurality of acquisition units on industrial production equipment; the acquisition unit sets an acquisition queue according to the capacity of the data parameters, performs node connection and elimination, converts the data parameters into quantum state data and transmits the quantum state data to the embedded gateway module;

the embedded gateway module is provided with a partition processing unit, a dynamic stacking unit and a distributing and pushing unit; the partition processing unit is used for partitioning the quantum state data to form partitioned quantum data, the dynamic push unit dynamically distributes the partitioned quantum data to a gateway storage stack, the distribution pushing unit is provided with a plurality of embedded gateway interfaces, and the partitioned quantum data in the gateway storage stack is distributed in a channel and pushed to the data processing module for processing;

the data processing module is connected with the embedded gateway interface and is used for processing the data according to different methods in the transmission process of the split area quantum data and when the transmission is finished; carrying out quantum communication encryption in the transmission process of a communication channel, and carrying out dynamic marking on the sub-region quantum data to generate dynamic data when the transmission of the sub-region quantum data is finished, so as to continuously change the position of the dynamic data;

the terminal display module is used for carrying out portable mobile terminal display and fixed terminal display on the dynamic data; the data report, the three-dimensional model and the gradient histogram generated by the terminal display module are downloaded, updated and printed through portable mobile terminal equipment, and a user uploads the data of the equipment through the portable mobile terminal equipment; the fixed terminal display is carried out through a fixed terminal main control machine, dynamic data in all portable mobile terminal equipment are summarized, a data matrix is generated according to the dynamic data for display, and authority assessment is carried out according to the type of the data matrix.

Further, the process of the data acquisition module for acquiring the data parameters through the acquisition unit comprises the following steps:

the method comprises the steps that a plurality of acquisition units are arranged on industrial production equipment to acquire data parameters, and the acquisition units set an acquisition queue according to the capacity of the data parameters;

the collection queue is provided with a standard capacity threshold, connection and elimination of collection queue nodes are carried out according to the capacity of the data parameters and the standard capacity threshold, and the data parameters are placed into the collection queue.

Further, the process of converting the data parameters into quantum state data includes:

obtaining data parameters in an acquisition queue, and performing quantization processing on the data parameters to generate quantum state data, wherein the fixed number of quantum state data is taken as a group;

the quantum state data in each group is divided into storage qubits and information qubits, wherein the storage qubits are used for storage processes, and the information qubits are used for information transmission;

when the quantum state data is transmitted, a plurality of quantum state data are transmitted simultaneously, each quantum state data is used as a task, a task timer is set, and the tasks are sequentially transmitted to the embedded gateway module.

Further, the process of the embedded gateway module for partitioning quantum state data, dynamically distributing a storage stack and distributing channels comprises the following steps:

the embedded gateway module comprises a partition processing unit, a dynamic stacking unit and a distributing and pushing unit;

the partition processing unit is used for partitioning the quantum state data to form partitioned quantum data;

the dynamic stacking unit dynamically distributes gateway storage stacks for storing the sub-region quantum data;

and the distribution pushing unit establishes a communication channel and performs channel distribution pushing of the regional quantum data.

Further, the process of partitioning operation includes:

quantum state data are subjected to quantum tag association through a partition processing unit, and a group of quantum state data are stored into a set data partition;

packaging the quantum tag into a folder, and taking the name of the data partition as the file name of the folder to form a first-level partition;

partitioning each quantum state data to form a secondary partition, taking the file name as the name prefix of the secondary partition, numbering each quantum state data from a, and forming the partition name of the secondary partition by the name prefix and the number;

and taking the quantum state data in the same secondary partition as a group of component area quantum data.

Further, the process of dynamically allocating the gateway storage stack includes:

the dynamic stacking unit dynamically adjusts and distributes the number of the gateway storage stacks according to the number in the second-level partition corresponding to the first-level partition;

when the number of the gateway storage stacks is smaller than the number of the secondary partitions, increasing the number of the gateway storage stacks;

when the number of the gateway storage stacks is larger than the number of the secondary partitions, reducing the number of the gateway storage stacks;

when the number of the gateway storage stacks is equal to the number of the secondary partitions, the number of the gateway storage stacks is not adjusted.

Further, the process of establishing the communication channel and pushing the channel distribution includes:

the distribution pushing unit is provided with a plurality of embedded gateway interfaces, and a corresponding communication channel is established through each embedded gateway interface;

acquiring the time of entering the communication channel of the sub-area quantum data, the time of entering the data processing module and the data quantity of the sub-area quantum data in the communication channel, thereby acquiring the channel transmission rate;

and setting a standard transmission rate range, and performing corresponding operation according to the standard transmission rate range and the channel transmission rate.

Further, the process of encrypting the communication channel transmission by the data processing module includes:

the method comprises the steps of connecting with a communication channel through an embedded gateway interface, and transferring sub-area quantum data which are being transmitted in the communication channel to a set encryption transfer area for encryption;

the encryption transfer area divides the regional quantum data into three parts, namely a data head, a data body and a data tail;

generating a primary key sequence by primary encryption on a data head, sequentially scrambling the primary key sequence on the basis of primary encryption on a data body, and generating a secondary key sequence by secondary encryption;

three-level encryption is adopted on the basis of the two-level key sequence for the data tail, and the data tail is converted into a binary sequence to generate a three-level key sequence;

and summarizing the primary key sequence, the secondary key sequence and the tertiary key sequence to generate encrypted data, and transmitting the encrypted data from the encryption transfer area to be dynamically marked.

Further, the process of dynamic marking includes:

setting a fixed time interval by taking a set of fixed number of encrypted data as a set of dynamic tags circularly endowed with G-Q, and taking the middle dynamic tag L of the set of encrypted data as a center axis datum point to adjust encrypted data at symmetrical positions of two sides;

when the exchange of the encrypted data of all groups is completed, taking each group of data as an object, setting the middle object as a center axis datum point to perform secondary symmetrical exchange, and converting the encrypted data after the secondary exchange is completed into dynamic data;

and a temporary transmission channel is established between the data processing module and the management center, and dynamic data is transmitted to the management center.

Further, the process of displaying dynamic data and performing authority assessment by the terminal display module comprises the following steps:

the terminal display module displays dynamic data in two modes of portable mobile terminal display and fixed terminal display;

generating a data report, a three-dimensional model and a gradient histogram from the dynamic data through the constructed display model;

a user in an industrial enterprise carries out inspection of a production line to which industrial production equipment belongs through portable mobile terminal equipment, and data information of the production line is recorded;

the production line data information comprises fault information and correct information, a data update form is generated according to the correct information and is uploaded to the terminal display module, an update instruction is generated by combining the fault information, and an administrator of the management center performs update operation;

setting a fixed terminal main control machine, summarizing dynamic data in all portable mobile terminal equipment through the fixed terminal main control machine, generating data matrixes with different specifications according to the dynamic data, and forming a unit cell by each row and each column for storing the dynamic data;

when the dynamic data in the portable mobile terminal device is abnormal, associating the unit cells with the abnormal marks as molecules, and forming a ratio by taking the unit cells with the abnormal marks as denominators;

and setting corresponding permission levels according to the range of the ratio and performing corresponding operation.

Compared with the prior art, the invention has the beneficial effects that: in the data acquisition stage, the connection and the elimination of the nodes of the acquisition queue are carried out according to the data parameter capacity of the industrial production equipment, so that the capacity redundancy and the capacity deficiency of the acquisition queue are avoided, the congestion caused by the excessive number of processes in unit time is avoided through the storage of the quantum bit and the information quantum bit, and the high concurrent execution of the data is ensured; the triple encryption measures, the symmetrical pair and the secondary symmetrical pair are set to realize continuous change of data encryption and data positions, so that the external network attack times and data leakage are reduced; the data is displayed in two modes, the data corresponding to the abnormal unit cells are set and associated with the abnormal marks, authority assessment is carried out according to the ratio, and corresponding measures are taken for maintenance, so that the purposes of gateway data display and management are achieved.

Drawings

Fig. 1 is a schematic diagram of the present invention.

Detailed Description

As shown in fig. 1, the quantum gateway data display management system comprises a management center, wherein the management center is in communication connection with a data acquisition module, an embedded gateway module, a data processing module and a terminal display module;

the data acquisition module acquires data parameters by arranging a plurality of acquisition units on industrial production equipment; the acquisition unit sets an acquisition queue according to the capacity of the data parameters, performs node connection and elimination, converts the data parameters into quantum state data and transmits the quantum state data to the embedded gateway module;

the embedded gateway module is provided with a partition processing unit, a dynamic stacking unit and a distributing and pushing unit; the partition processing unit is used for partitioning the quantum state data to form partitioned quantum data, the dynamic push unit dynamically distributes the partitioned quantum data to a gateway storage stack, the distribution pushing unit is provided with a plurality of embedded gateway interfaces, and the partitioned quantum data in the gateway storage stack is distributed in a channel and pushed to the data processing module for processing;

the data processing module is connected with the embedded gateway interface and is used for processing the data according to different methods in the transmission process of the split area quantum data and when the transmission is finished; carrying out quantum communication encryption in the transmission process of a communication channel, and carrying out dynamic marking on the sub-region quantum data to generate dynamic data when the transmission of the sub-region quantum data is finished, so as to continuously change the position of the dynamic data;

the terminal display module is used for carrying out portable mobile terminal display and fixed terminal display on the dynamic data; the data report, the three-dimensional model and the gradient histogram generated by the terminal display module are downloaded, updated and printed through portable mobile terminal equipment, and a user uploads the data of the equipment through the portable mobile terminal equipment; the fixed terminal display is carried out through a fixed terminal main control machine, dynamic data in all portable mobile terminal equipment are summarized, a data matrix is generated according to the dynamic data for display, and authority assessment is carried out according to the type of the data matrix.

Specifically, the process that the data acquisition module acquires data parameters through the acquisition unit comprises the following steps:

arranging a plurality of acquisition units on industrial production equipment, wherein each acquisition unit acquires data parameters, and the acquisition units set an acquisition queue according to the capacity of the data parameters;

the acquisition queue is provided with a standard capacity threshold value which is marked as V, and the capacity of the data parameter acquired by each acquisition unit is marked as V _i I e 1,2,3., n, n is a natural number;

if V _i Performing an expansion operation of the acquisition queue if V is greater than V, acquiring a plurality of nodes included in the acquisition queue, wherein each node is provided with a fixed capacity and is marked as V _j J is E1, 2,3, m, m is a natural number, an mth node is obtained, the mth node is taken as a tail node, and an expansion node with fixed capacity is connected with the tail node to realize expansion, V _j And expanding the capacity formed by the nodes to a new V, up to V _i V is not more than, and connection of the expansion nodes is stopped;

if V _i And (2) performing scaling operation on the acquisition queue, acquiring a plurality of nodes included in the acquisition queue, wherein each node is provided with a fixed capacity and is marked as V _k K is a natural number, p and p are obtained, the p node is taken as a starting node, node rejection is carried out, and the capacity V of the acquisition queue is updated every time one node is rejected until V _i The node eliminating operation is stopped if the node is not less than V;

if V _i =v, directly pushing the data parameters into the acquisition queue without adding or removing nodes;

it should be noted that, according to the size of the capacity of the data parameter, the number of the collected nodes is selected to be increased or removed, so as to achieve the control of the capacity of the collection queue, avoid redundancy caused by adopting the collection queue with the overlarge capacity, and avoid the loss of the data parameter caused by the collection queue with the overlarge capacity.

Specifically, the process of converting the data parameters into quantum state data includes:

the method comprises the steps of obtaining data parameters in an acquisition queue, performing quantization processing on the data parameters to generate quantum state data, taking fixed number of quantum state data as a group, dividing the quantum state data in each group into storage quantum bits and information quantum bits, wherein the storage quantum bits are used for storage processes, and the information quantum bits are used for information transmission;

the storage qubit is provided with two states of stored and in-store, when the state is in-store, the current process is destroyed, a new process is created for storing the next data parameter, when the state is in-store, the current process is limited by timing, the process is destroyed when the timing is finished, and if the timing is finished, the state is not changed, the new process is generated;

the information qubit has parallelism, when quantum state data are transmitted, a plurality of quantum state data are transmitted simultaneously, each quantum state data is used as a task, a task timer is set, and the tasks are sequentially transmitted to the embedded gateway module;

it should be noted that, by storing the settings of different states of the qubit and destroying the processes according to the states, the number of processes in unit time is ensured not to be excessive, congestion phenomenon is caused, and the information qubit exists, so that high concurrency of data can be performed;

the process of the embedded gateway module for partitioning quantum state data, dynamically distributing a storage stack and distributing channels comprises the following steps:

the embedded gateway module comprises a partition processing unit, a dynamic stacking unit and a distributing and pushing unit;

the partition processing unit is used for partitioning the quantum state data to form partitioned quantum data;

the dynamic stacking unit dynamically distributes gateway storage stacks for storing the sub-region quantum data;

the distribution pushing unit establishes a communication channel and carries out channel distribution pushing of the regional quantum data;

specifically, the process of the partitioning operation includes:

the quantum state data carries quantum labels according to ten groups of cycles through a partition processing unit, and the quantum labels are associated with quantum state data corresponding to industrial production equipment;

storing a group of quantum state data into a set data partition, packaging a quantum label into a folder, and forming a first-level partition by taking the name of the data partition as the file name of the folder;

further partitioning each quantum state data to form a secondary partition, taking the file name as the name prefix of the secondary partition, numbering each quantum state data from a, and forming the partition name of the secondary partition by the name prefix and the number;

all quantum state data in the same secondary region are called as sub-region quantum data of one region, and the sub-region quantum data are transmitted to a gateway storage stack for storage;

specifically, the process of dynamically allocating the gateway storage stack includes:

the dynamic stacking unit dynamically adjusts and distributes the number of the gateway storage stacks according to the number in the second-level partition corresponding to the first-level partition;

recording the number of gateway storage stacks as Num1, the number of secondary partitions as Num2, and increasing the number of gateway storage stacks when Num1 is less than Num 2; when Num1 > Num2, reducing the number of gateway storage stacks; when Num 1=num 2, the number of gateway storage stacks is not adjusted;

specifically, the process of establishing the communication channel and pushing the channel distribution includes:

the distribution pushing unit is provided with a plurality of embedded gateway interfaces, a corresponding communication channel is established through each embedded gateway interface, and the serial number of the embedded gateway interface is used as the serial number of the communication channel;

acquiring time T1 of entering the communication channel of the sub-area quantum data, time T2 of entering the data processing module, and data quantity M of the sub-area quantum data in the communication channel, thereby acquiring channel transmission rate V _{Transmission device} ＝M/(T2－T1)bit/s；

Setting a standard transmission rate range to be 200 bit/s-800 bit/s, temporarily closing the embedded gateway interface if the channel transmission rate is not in the standard transmission rate range, marking Error, and sequentially distributing and pushing the sub-area quantum data to a data processing module for processing through a communication channel if the channel transmission rate is in the standard transmission rate range;

it should be noted that, the number of gateway storage stacks is dynamically increased and reduced, so that the influence of excessive gateway storage stacks on the performance of the gateway is avoided, and whether the embedded gateway interface has faults or not is judged by monitoring the transmission rate of each communication channel, so that corresponding measures are set.

The process of encrypting the communication channel transmission by the data processing module comprises the following steps:

the data processing module is connected with the communication channel through the embedded gateway interface, and after the data processing module is accessed into the communication channel, the sub-area quantum data which is being transmitted in the communication channel is transferred to a set encryption transfer area for encryption;

the encryption transfer area divides the regional quantum data into three parts, namely a data head, a data body and a data tail;

the method comprises the steps of adopting primary encryption in quantum communication encryption to a data head to generate a primary key sequence, sequentially scrambling the primary key sequence on the basis of primary encryption to generate a secondary key sequence, adopting tertiary encryption on the basis of the secondary key sequence to convert the primary key sequence into a binary sequence to generate a tertiary key sequence;

summarizing the primary key sequence, the secondary key sequence and the tertiary key sequence to generate encrypted data, and transmitting the encrypted data from an encryption transfer area to be dynamically marked;

the process of dynamically marking the encrypted data formed by the encryption comprises the following steps:

acquiring encrypted data, and circularly endowing G-Q dynamic tags with 11 encrypted data as a group;

setting a fixed time interval, and changing the encrypted data at symmetrical positions of two sides by taking the middle dynamic tag L of a group of encrypted data as a center axis datum point and taking the center axis datum point as a symmetry axis every time the fixed time interval is reached;

after the whole encryption data are exchanged, the next encryption data are symmetrically exchanged, after the encryption data of all groups are exchanged, each group of data are sequentially arranged, each group of data is taken as an object, the middle object is set as a center axis datum point, and after the second encryption data are converted into dynamic data after the second encryption data are exchanged, the second encryption data are symmetrically exchanged for a second time at fixed time intervals;

a temporary transmission channel is established between the data processing module and the management center, and dynamic data is transmitted to the management center;

it is further described that, triple encryption measures of primary encryption, secondary encryption and tertiary encryption are adopted, data security is guaranteed, symmetric exchange of each group of encrypted data is carried out through fixed time intervals, secondary symmetric exchange is carried out on all groups of encrypted data which are subjected to symmetric exchange, and therefore the position of each data is continuously changed, the difficulty of network attack by the outside is improved, and the number of network attacks and leakage loss of data are reduced.

The terminal display module displays dynamic data in two modes of portable mobile terminal display and fixed terminal display;

the terminal display module is used for reading dynamic data stored in the management center by establishing a temporary data reading space with the management center, and destroying the temporary data reading space after the data reading is completed;

the dynamic data comprises time parameters and data parameters, wherein the time parameters are generated according to fixed time intervals, the data parameters are the content of the dynamic data, a display model is built, and the time parameters and the data parameters are input into the display model to respectively generate a data report, a three-dimensional model and a gradient histogram;

a user in an industrial enterprise carries out inspection of a production line to which industrial production equipment belongs through portable mobile terminal equipment, and the portable mobile terminal equipment records all production line data information in the production line;

the production line data information comprises fault information and correct information, a data update form is generated according to the correct information, a user can download a data report, a three-dimensional model and a gradient histogram through portable mobile terminal equipment, and the portable mobile terminal equipment can be connected with printing equipment for printing;

uploading data update forms in the portable mobile terminal devices to a terminal display module, generating update instructions in combination with fault information, and selecting whether to perform update operations of the data report, the three-dimensional model and the gradient histogram by an administrator arranged at a management center according to the update instructions;

specifically, the process of generating a data matrix by displaying dynamic data through a fixed terminal and performing authority assessment includes:

setting a fixed terminal main control machine, and summarizing dynamic data in all portable mobile terminal devices through the fixed terminal main control machine;

generating data matrixes with different specifications according to dynamic data, wherein the specifications comprise 5×5, 7×7 and 9×9, and each row and each column form a unit cell for storing one dynamic data;

acquiring the number of unit cells corresponding to the data matrix, marking as alpha, when the dynamic data in the portable mobile terminal equipment is abnormal, associating the unit cells with an abnormal mark False, marking the number of the abnormal marks as beta, and performing authority assessment according to the ratio of the alpha to the beta;

if beta/alpha epsilon [0,1/3], setting a first-level authority, carrying out self-checking correction on industrial production equipment, importing industrial production equipment related data into a database, and resetting equipment parameters;

if the beta/alpha E (1/3, 1/2), setting a secondary authority, and stopping the data uploading and the data updating authority of the portable mobile terminal equipment;

if the beta/alpha E (1/2, 1), setting three-level authority, prohibiting a user from performing all operations, generating a fault report and repair form, uploading the fault report and repair form to a management center, and enabling a management center manager to carry out overhaul of portable mobile terminal equipment and industrial production equipment according to a fault report and repair form single-service technician;

it should be further explained that the data matrixes with different specifications are set to improve the utilization rate of the matrixes, and the ratio of abnormal unit cells to total unit cells is evaluated in authority, so that corresponding measures are taken to achieve the purpose of overhauling industrial production equipment and portable mobile terminal equipment.

The above embodiments are only for illustrating the technical method of the present invention and not for limiting the same, and it should be understood by those skilled in the art that the technical method of the present invention may be modified or substituted without departing from the spirit and scope of the technical method of the present invention.

Claims (7)

1. The quantum gateway data display management system comprises a management center and is characterized in that the management center is in communication connection with a data acquisition module, an embedded gateway module, a data processing module and a terminal display module;

the data acquisition module acquires data parameters by arranging a plurality of acquisition units on industrial production equipment; the acquisition unit sets an acquisition queue according to the capacity of the data parameters, performs node connection and elimination, acquires the data parameters in the acquisition queue, performs quantization processing on the data parameters to generate quantum state data, and takes a fixed number of quantum state data as a group; the quantum state data in each group is divided into storage quantum bits and information quantum bits, wherein the storage quantum bits are used for storing processes, and the information quantum bits are used for information transmission; the storage qubit is provided with two states of stored and in-store, when the state is in-store, the current process is destroyed, a new process is created for storing the next data parameter, when the state is in-store, the current process is limited by timing, the process is destroyed when the timing is finished, and if the timing is finished, the state is not changed yet, the new process is generated; when quantum state data is transmitted, a plurality of quantum state data are transmitted simultaneously, each quantum state data is taken as a task, a task timer is set, and the tasks are sequentially transmitted to the embedded gateway module;

the embedded gateway module is provided with a partition processing unit, a dynamic stacking unit and a distributing and pushing unit; the partition processing unit is used for partitioning the quantum state data to form partitioned quantum data, the dynamic push unit dynamically distributes the partitioned quantum data to a gateway storage stack, the distribution pushing unit is provided with a plurality of embedded gateway interfaces, and the partitioned quantum data in the gateway storage stack is distributed in a channel and pushed to the data processing module for processing;

the data processing module is connected with the embedded gateway interface and is used for processing the data according to different methods in the transmission process of the split area quantum data and when the transmission is finished; carrying out quantum communication encryption in the transmission process of a communication channel, and carrying out dynamic marking on the sub-region quantum data to generate dynamic data when the transmission of the sub-region quantum data is finished, so as to continuously change the position of the dynamic data;

the process of encrypting the communication channel transmission by the data processing module comprises the following steps:

the method comprises the steps of connecting with a communication channel through an embedded gateway interface, and transferring sub-area quantum data which are being transmitted in the communication channel to a set encryption transfer area for encryption;

the encryption transfer area divides the regional quantum data into three parts, namely a data head, a data body and a data tail;

generating a primary key sequence by primary encryption on a data head, sequentially scrambling the primary key sequence on the basis of primary encryption on a data body, and generating a secondary key sequence by secondary encryption;

three-level encryption is adopted on the basis of the two-level key sequence for the data tail, and the data tail is converted into a binary sequence to generate a three-level key sequence;

summarizing the primary key sequence, the secondary key sequence and the tertiary key sequence to generate encrypted data, and transmitting the encrypted data from an encryption transfer area to be dynamically marked;

the process of dynamic marking includes:

setting a fixed time interval by taking a set of fixed number of encrypted data as a set of dynamic tags circularly endowed with G-Q, and taking the middle dynamic tag L of the set of encrypted data as a center axis datum point to adjust encrypted data at symmetrical positions of two sides;

when the exchange of the encrypted data of all groups is completed, taking each group of data as an object, setting the middle object as a center axis datum point to perform secondary symmetrical exchange, and converting the encrypted data after the secondary exchange is completed into dynamic data;

a temporary transmission channel is established between the data processing module and the management center, and dynamic data is transmitted to the management center;

the terminal display module is used for carrying out portable mobile terminal display and fixed terminal display on the dynamic data; the data report, the three-dimensional model and the gradient histogram generated by the terminal display module are downloaded, updated and printed through portable mobile terminal equipment, and a user uploads the data of the equipment through the portable mobile terminal equipment; the fixed terminal display is carried out through a fixed terminal main control machine, dynamic data in all portable mobile terminal equipment are summarized, a data matrix is generated according to the dynamic data for display, and authority assessment is carried out according to the type of the data matrix.

2. The quantum gateway data display management system of claim 1, wherein the process of the data acquisition module for data parameter acquisition by the acquisition unit comprises:

the method comprises the steps that a plurality of acquisition units are arranged on industrial production equipment to acquire data parameters, and the acquisition units set an acquisition queue according to the capacity of the data parameters;

the collection queue is provided with a standard capacity threshold, connection and elimination of collection queue nodes are carried out according to the capacity of the data parameters and the standard capacity threshold, and the data parameters are placed into the collection queue.

3. The quantum gateway data display management system of claim 2, wherein the process of the embedded gateway module for partitioning, dynamically allocating storage stacks and channel distribution of quantum state data comprises:

the embedded gateway module comprises a partition processing unit, a dynamic stacking unit and a distributing and pushing unit;

the partition processing unit is used for partitioning the quantum state data to form partitioned quantum data;

the dynamic stacking unit dynamically distributes gateway storage stacks for storing the sub-region quantum data;

and the distribution pushing unit establishes a communication channel and performs channel distribution pushing of the regional quantum data.

4. The quantum gateway data display management system of claim 3, wherein the process of partitioning comprises:

quantum state data are subjected to quantum tag association through a partition processing unit, and a group of quantum state data are stored into a set data partition;

packaging the quantum tag into a folder, and taking the name of the data partition as the file name of the folder to form a first-level partition;

partitioning each quantum state data to form a secondary partition, taking the file name as the name prefix of the secondary partition, numbering each quantum state data from a, and forming the partition name of the secondary partition by the name prefix and the number;

and taking the quantum state data in the same secondary partition as a group of component area quantum data.

5. The quantum gateway data display management system of claim 4, wherein the process of dynamically allocating the gateway storage stack comprises:

the dynamic stacking unit dynamically adjusts and distributes the number of the gateway storage stacks according to the number in the second-level partition corresponding to the first-level partition;

when the number of the gateway storage stacks is smaller than the number of the secondary partitions, increasing the number of the gateway storage stacks;

when the number of the gateway storage stacks is larger than the number of the secondary partitions, reducing the number of the gateway storage stacks;

when the number of the gateway storage stacks is equal to the number of the secondary partitions, the number of the gateway storage stacks is not adjusted.

6. The quantum gateway data display management system of claim 5, wherein the process of establishing and pushing channel distribution of the communication channel comprises:

the distribution pushing unit is provided with a plurality of embedded gateway interfaces, and a corresponding communication channel is established through each embedded gateway interface;

acquiring the time of entering the communication channel of the sub-area quantum data, the time of entering the data processing module and the data quantity of the sub-area quantum data in the communication channel, thereby acquiring the channel transmission rate;

and setting a standard transmission rate range, and performing corresponding operation according to the standard transmission rate range and the channel transmission rate.

7. The quantum gateway data display management system of claim 6, wherein the process of displaying dynamic data and performing rights assessment by the terminal display module comprises:

the terminal display module displays dynamic data in two modes of portable mobile terminal display and fixed terminal display;

generating a data report, a three-dimensional model and a gradient histogram from the dynamic data through the constructed display model;

a user in an industrial enterprise carries out inspection of a production line to which industrial production equipment belongs through portable mobile terminal equipment, and data information of the production line is recorded;

the production line data information comprises fault information and correct information, a data update form is generated according to the correct information and is uploaded to the terminal display module, an update instruction is generated by combining the fault information, and an administrator of the management center performs update operation;

setting a fixed terminal main control machine, summarizing dynamic data in all portable mobile terminal equipment through the fixed terminal main control machine, generating data matrixes with different specifications according to the dynamic data, and forming a unit cell by each row and each column for storing the dynamic data;

when the dynamic data in the portable mobile terminal device is abnormal, associating the unit cells with the abnormal marks as molecules, and forming a ratio by taking the unit cells with the abnormal marks as denominators;

and setting corresponding permission levels according to the range of the ratio and performing corresponding operation.

Images