CN114978216B - Multi-source data processing system based on Internet of things - Google Patents

Abstract

The invention discloses a multi-source data processing system based on the Internet of things, and relates to the technical field of multi-source data processing. The invention includes a multi-source data processing mechanism; the multi-source data processing mechanism comprises a main processor, a plurality of peripheral processors electrically connected below the main processor and a display assembly connected to the main processor and the middle part of the upper end of the peripheral processors; the system also comprises a data transmission mechanism connected with the output and input ends of the main processor and the peripheral processor. According to the invention, by arranging the multi-source data processing mechanism and the data transmission mechanism, the increase and decrease of the peripheral processors are reasonably carried out, so that the reasonable distribution of the processing capacity is satisfied, the resource consumption is reduced, and the cost is saved; the first wiring pipe, the second wiring pipe and the magnetic columns are additionally arranged, and under the magnetic attraction of a group of magnetic columns, the connection between the main processor and the peripheral processor is realized under the condition that the stable conveying line is ensured; meanwhile, the folding and unfolding frame is additionally arranged to carry out folding and unfolding operation of the conveying line so as to meet different use requirements and facilitate use.

Description

Multi-source data processing system based on Internet of things

Technical Field

The invention belongs to the technical field of multi-source data processing, and particularly relates to a multi-source data processing system based on the Internet of things.

Background

Multisource data includes a variety of resolution data, multidimensional data, and various types of data that differ in terms of data form such as format, unit, resolution, precision, and internal features of the data such as attributes, content, etc. The digital map is a centralized representation of multi-source data, is a main body of the multi-source data, and mainly comprises a Digital Line Graph (DLG), a Digital Raster Graph (DRG), a digital orthogonal image graph (DOM), a Digital Elevation Model (DEM), various digital thematic maps and the like, and the data processing device belongs to multi-source data processing equipment.

Through retrieval, china's patent number CN114006928A, grant publication date 2022.02.01, grant discloses an Internet of things data processing method based on multi-protocol real-time communication, comprising: storing the data of the Internet of things according to data types, wherein each data type corresponds to an independent data storage space; acquiring service data from the data storage space according to a multi-protocol communication request; determining a data conversion rule based on communication protocol information in the multi-protocol communication request, and obtaining target data based on the data conversion rule; the data of the Internet of things is classified and stored, so that the data can be searched and acquired, the data can be converted based on the multi-protocol communication request, the transmission and interaction of the target data between different communication protocols or different servers can be realized, and the target data can be used conveniently.

However, in the existing multi-source data processing system, after processing is performed by the main processing device, a plurality of peripheral servers are generally added for matched data processing so as to improve the data processing efficiency, and no matter how much data is processed, the processing is performed under the same number of peripheral servers, so that resources are consumed, and the cost is increased;

therefore, the existing multi-source data processing system based on the internet of things cannot meet the requirements in practical use, so that there is an urgent need for an improved technology in the market to solve the above-mentioned problems.

Disclosure of Invention

The invention aims to provide a multi-source data processing system based on the Internet of things, which solves the problems in the background technology by arranging a multi-source data processing mechanism and a data transmission mechanism.

In order to solve the technical problems, the invention is realized by the following technical scheme:

the invention relates to a multi-source data processing system based on the Internet of things, which comprises a multi-source data processing mechanism;

the multi-source data processing mechanism comprises a main processor, a plurality of peripheral processors electrically connected below the main processor and a display assembly connected to the main processor and the middle part of the upper end of the peripheral processors;

the main processor and the peripheral processor are internally provided with:

the data receiving unit is used for receiving the externally conveyed multi-source data;

the data transmission unit is used for transmitting the received multi-source data to the data overall unit;

the data overall planning unit is used for carrying out centralized overall planning on the transmitted multi-source data;

the singlechip is used for analyzing and processing the multi-source data after overall planning;

the data distribution unit distributes large-capacity overall multi-source data;

the system also comprises a data transmission mechanism connected with the output and input ends of the main processor and the peripheral processor.

Further, the main processor and the peripheral processor comprise an outer shell, radiating ports which are equidistantly and penetratingly connected to the middle parts of two sides of the outer shell, a shell cover which is connected to the upper part of the front surface of the outer shell, and an auxiliary control assembly which is connected to the lower part of the front surface of the outer shell;

the middle parts of the front ends of the two sides of the shell cover are provided with groove structures;

specifically, the outer shell provides the storage installation space of the following processing unit, and the cooling port then carries out the inside heat dissipation of outer shell, and the cap carries out the outer seal protection to outer shell inner structure to and the taking of the inner structure of being convenient for is put, and auxiliary control subassembly then carries out the device peripheral hardware and controls the accepting of keyboard.

Further, the auxiliary control assembly comprises a group of support blocks, a support plate connected to the inner side of the support blocks through screws and a rubber hand support connected to the front part of the upper end of the support plate;

the center of the supporting plate is provided with a rectangular groove structure;

specifically, the support block carries out the bearing of the supporting plate through the screw rod so as to carry out the bearing and fixing of the peripheral keyboard under the positioning of the rectangular groove through the supporting plate, and the hand rest provides good control comfort for the control personnel.

Further, the outer shell is internally provided with:

the data receiving unit is used for receiving the externally conveyed multi-source data;

the data transmission unit is used for transmitting the next unit in the device to the received multi-source data;

the data overall planning unit is used for carrying out centralized overall planning on the transmitted multi-source data;

the singlechip is used for analyzing and processing the multi-source data after overall planning;

and the data distribution unit distributes the large-capacity overall multi-source data to the main processor or the plurality of peripheral processors.

Further, the display assembly comprises a ring block, a shaft seat connected to the upper end of the ring block and a display screen connected to the upper end of the shaft seat;

the ring blocks are connected with the upper end of the outer shell through fastening bolts penetrating through the middle part at equal intervals;

specifically, the ring block is connected with the shaft seat under the fastening bolt, the shaft seat is used for carrying and fixing the display screen and performing multi-angle adjustment of the display screen, and the display screen is used for controlling steps and displaying data in real time.

Further, the data transmission mechanism comprises interfaces which are equidistantly connected to the lower parts of the rear ends of the main processor and the peripheral processor, and a transmission line which is connected to one interface, and a wiring assembly of which the end part is respectively connected with one end of the transmission line and the other interface;

specifically, the interface carries out connection assembly and the bearing of transfer chain to carry out the connection between transfer chain and main processor, the peripheral hardware treater through connection assembly, in order to carry out the transportation of data.

Further, the wiring assembly comprises a first wiring pipe, a second wiring pipe sleeved and connected to the front end of the first wiring pipe, a driving motor penetrating and connected to the middle part of the front end of the second wiring pipe, a rotating shaft connected to the output end of the driving motor and a retraction frame connected to the front end of the rotating shaft;

specifically, the first wiring pipe is connected with the second wiring pipe in a sleeved mode, a moving guide space of the conveying line is provided, and the driving motor applies rotating force to the winding and unwinding frame to adjust the length of the conveying line, so that the requirement in use is met.

Further, the rear end of the inside of the wiring tube and one end of the conveying line are connected with magnetic columns, and the magnetism of one group of the magnetic columns is arranged in different directions;

specifically, magnetism between a set of magnetic beads is opposite to setting, under opposite phase attraction to and under the activity of pivot, make transfer chain one end extend into a wiring pipe inside, transfer chain and a wiring pipe inside wall contact, and wiring pipe one be metal conductive structure, can carry out the quick electric connection between main processor and the peripheral hardware treater.

The invention has the following beneficial effects:

the invention processes the multi-source data through the main processor and adds a plurality of peripheral processors in the same way as the prior art so as to improve the efficiency of processing the multi-source data, but under the knowledge of the processing amount of the multi-source data, the data distribution unit distributes the multi-source data to the peripheral processors with the corresponding number, thereby reducing the resource consumption and saving the cost while meeting the reasonable distribution of the processing amount;

the first wiring pipe, the second wiring pipe and the magnetic column are additionally arranged, the second wiring pipe is of an insulating structure, the first wiring pipe is of a conductive metal structure, and under the magnetic attraction of a group of magnetic columns, the connection between the main processor and the peripheral processor is realized under the condition that the stable state of the conveying line is ensured;

meanwhile, the retractable frame is additionally arranged, and the retractable operation of the conveying line is carried out through the retractable frame under the driving motor, so that different use requirements are met, and the retractable frame is easy to use.

Of course, it is not necessary for any one product to practice the invention to achieve all of the advantages set forth above at the same time.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings that are needed for the description of the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a front view of the present invention;

FIG. 2 is a rear view of the present invention;

FIG. 3 is a block diagram of a data transmission mechanism according to the present invention;

FIG. 4 is a block diagram of a wiring assembly of the present invention;

FIG. 5 is a block diagram of a host processor in accordance with the present invention;

fig. 6 is a flow chart of the present invention.

In the drawings, the list of components represented by the various numbers is as follows:

1. a multi-source data processing mechanism; 100. a main processor; 200. a peripheral processor; 110. an outer housing; 120. a heat radiation port; 130. a cover; 140. an auxiliary control assembly; 141. a support block; 142. a screw; 143. a supporting plate; 144. a hand support; 300. a display assembly; 310. a ring block; 320. a shaft seat; 330. a display screen; 400. a data transmission mechanism; 410. an interface; 420. a conveying line; 430. a wiring assembly; 431. a first wiring pipe; 432. a second wiring pipe; 433. a drive motor; 434. a rotating shaft; 435. a retractable frame; 436. and a magnetic column.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention.

Example 1

Referring to fig. 5-6, the present embodiment is a multi-source data processing system based on the internet of things, including a multi-source data processing mechanism 1;

the multi-source data processing mechanism 1 comprises a main processor 100, a plurality of peripheral processors 200 electrically connected below the main processor 100 and a display assembly 300 connected to the upper middle parts of the main processor 100 and the peripheral processors 200;

the main processor 100 and the peripheral processor 200 each comprise an outer shell 110, heat dissipation ports 120 penetrating through the middle parts of two sides of the outer shell 110 at equal intervals, a shell cover 130 connected to the upper part of the front surface of the outer shell 110, and an auxiliary control assembly 140 connected to the lower part of the front surface of the outer shell 110;

the middle parts of the front ends of the two sides of the shell cover 130 are provided with groove structures;

when the multi-source data processing means 1 is used and the power is supplied to the apparatus by the external power supply, the following means perform operations:

the data receiving unit is used for receiving the externally conveyed multi-source data;

the data transmission unit transmits the received multi-source data to the data overall unit;

the data overall planning unit is used for carrying out centralized overall planning on the transmitted multi-source data;

the singlechip carries out fusion analysis processing on the multi-source data after overall planning;

the multi-source data fusion technology is a technology for integrating all information obtained by investigation and analysis by utilizing a related means, uniformly evaluating the information and finally obtaining uniform information;

the data distribution unit may distribute the large-capacity integrated multi-source data to the main processor 100 or a plurality of peripheral processors 200 with a suitable number.

Example 2

As shown in fig. 3-4, the device further comprises a data transmission mechanism 400 connected to the output and input ends of the main processor 100 and the peripheral processor 200;

the data transmission mechanism 400 comprises an interface 410 equidistantly connected to the lower parts of the rear ends of the main processor 100 and the peripheral processor 200, a transmission line 420 connected to one interface 410, and a wiring assembly 430 with the end part connected to one end of the transmission line 420 and the other interface 410 respectively;

the wiring assembly 430 comprises a first wiring tube 431 and a second wiring tube 432 which is sleeved and connected to the front end of the first wiring tube 431;

the rear end of the inside of the first connection pipe 431 and one end of the conveying line 420 are connected with magnetic columns 436, and the magnetism of one group of magnetic columns 436 is arranged in different directions;

after one end of the transmission line 420 is connected with one interface 410 on the main processor 100, the other end of the transmission line 420 extends into a second wiring pipe 432 in advance, and is connected with a winding and unwinding frame 435 in a winding way, and a magnetic column 436 is connected;

at this time, another magnetic pillar 436 is inserted into the first wire connection pipe 431 and connected to the interface 410 of the peripheral processor 200;

then, a group of magnetic columns 436 within a rated range are attracted to each other, and under the opposite attraction force and the rotation of the rotating shaft 434, the group of magnetic columns 436 are attracted to each other and contacted, and the conveying line 420 is contacted with the inner side wall of the first connection tube 431 with a metal conductive structure, so that the connection between the main processor 100 and one peripheral processor 200 is performed;

when the connection to the plurality of peripheral processors 200 is performed, the same steps as described above may be performed by the single chip microcomputer and the data distribution unit.

Example 3

As shown in fig. 4, the device further comprises a driving motor 433 penetrating through the middle part of the front end of the second connection pipe 432, a rotating shaft 434 connected to the output end of the driving motor 433, and a retractable frame 435 connected to the front end of the rotating shaft 434;

the length of the conveyor line 420 is adjusted, the driving motor 433 applies a rotational force to the rack 435, and the rack 435 is wound with the appropriate length of the conveyor line 420 by forward or reverse rotation of the shaft 434.

The foregoing is only a preferred embodiment of the present invention, and the present invention is not limited thereto, and any modification, equivalent replacement, and improvement of some of the technical features described in the foregoing embodiments are all within the scope of the present invention.

Claims (7)

1. A multi-source data processing system based on the Internet of things comprises a multi-source data processing mechanism (1);

the method is characterized in that;

the multi-source data processing mechanism (1) comprises a main processor (100), a plurality of peripheral processors (200) electrically connected below the main processor (100) and a display assembly (300) connected to the main processor (100) and the middle part of the upper end of the peripheral processors (200);

the main processor (100) and the peripheral processor (200) are internally provided with:

the data receiving unit is used for receiving the externally conveyed multi-source data;

the data transmission unit is used for transmitting the received multi-source data to the data overall unit;

the data overall planning unit is used for carrying out centralized overall planning on the transmitted multi-source data;

the singlechip is used for analyzing and processing the multi-source data after overall planning;

the data distribution unit of the main processor (100) distributes large-capacity overall multi-source data to the main processor (100) or a plurality of peripheral processors (200);

the system also comprises a data transmission mechanism (400) connected with the output end of the main processor (100) and the input end of the peripheral processor (200).

2. The internet of things-based multi-source data processing system according to claim 1, wherein the main processor (100) and the peripheral processor (200) each comprise an outer shell (110), heat dissipation ports (120) penetrating through the middle parts of two sides of the outer shell (110) at equal intervals, a shell cover (130) connected to the upper part of the front surface of the outer shell (110), and an auxiliary control assembly (140) connected to the lower part of the front surface of the outer shell (110);

the middle parts of the front ends of the two sides of the shell cover (130) are provided with groove structures.

3. The internet of things-based multi-source data processing system according to claim 2, wherein any one of the auxiliary control components (140) comprises a group of support blocks (141), a support plate (143) connected to the inner side of the support block (141) through a screw (142), and a rubber hand rest (144) connected to the front part of the upper end of the support plate (143);

the center of the supporting plate (143) is provided with a rectangular groove structure.

4. The internet of things-based multi-source data processing system according to claim 1, wherein the display assembly (300) comprises a ring block (310), an axle seat (320) connected to the upper end of the ring block (310), and a display screen (330) connected to the upper end of the axle seat (320);

the ring blocks (310) are connected with the upper end of the outer shell (110) through fastening bolts penetrating through the middle part at equal intervals.

5. The internet of things-based multi-source data processing system according to claim 1, wherein the data transmission mechanism (400) comprises an interface (410) equidistantly connected to the lower part of the rear end of the main processor (100) and the peripheral processor (200), a transmission line (420) connected to one of the interfaces (410), and a wiring assembly (430) with an end part connected to one end of the transmission line (420) and the other interface (410).

6. The internet of things-based multi-source data processing system according to claim 5, wherein the wiring assembly (430) comprises a first wiring pipe (431), a second wiring pipe (432) connected to the front end of the first wiring pipe (431) in a sleeved mode, a driving motor (433) connected to the middle of the front end of the second wiring pipe (432) in a penetrating mode, a rotating shaft (434) connected to the output end of the driving motor (433), and a retractable frame (435) connected to the front end of the rotating shaft (434).

7. The internet of things-based multi-source data processing system according to claim 6, wherein a magnetic column (436) is connected to an inner rear end of the first connection tube (431) and one end of the conveying line (420), and a set of magnetic anisotropy of the magnetic column (436) is set.