CN113051589A

CN113051589A - Big data government affair analysis and processing safety application platform

Info

Publication number: CN113051589A
Application number: CN202110285408.8A
Authority: CN
Inventors: 杨琴; 师铭; 姚平波
Original assignee: Chongqing Yangcheng Big Data Technology Co ltd
Current assignee: Chongqing Yangcheng Big Data Technology Co ltd
Priority date: 2021-03-17
Filing date: 2021-03-17
Publication date: 2021-06-29
Anticipated expiration: 2041-03-17
Also published as: CN113051589B

Abstract

The invention provides a big data government affair analysis and processing safety application platform which comprises a data acquisition module, a data processing and transmitting module and a data verification and display module, wherein the data acquisition module is used for acquiring and displaying big data; the data acquisition module is used for acquiring user information; the data processing and transmitting module is used for processing the user information acquired by the data acquisition module and transmitting the processed user information to the cloud platform; and the data verification display module is used for displaying the data information corresponding to the user on the touch display screen after the cloud platform verifies. The invention can play a protective role in government affair safety and avoid being attacked.

Description

Big data government affair analysis and processing safety application platform

Technical Field

The invention relates to the technical field of platforms, in particular to a big data government affair analysis and processing safety application platform.

Background

With the development of network technology, the improvement of intelligence and the increase of popularity of intelligent terminals, service departments increasingly rely on providing service items by means of networks, particularly government affair services provided by government departments, and most of the services can be inquired or transacted by means of the intelligent terminals through the networks. Patent application No. 2014104300096, entitled "government affairs service guide method and system", discloses obtaining GPS information and item keywords submitted by a user through an intelligent terminal; determining an administrative division to which the current position of the user belongs according to the GPS information; retrieving a preset item index library according to the item keywords, acquiring items matched with the item keywords from the item index library, and forming an item list for a user to select; acquiring a item selection result of a user, and searching a preset item service department portal library according to the item selected by the user to obtain a department set with the item handling authority; and according to the position information of all departments in the department set, acquiring the information of the department which is positioned in the administrative division and is closest to the position of the user in the GPS information from the department set, and forming a department list for the user to check or select. Although the invention perfects the guide service of the service system, in particular to a government affair service system, not only brings great convenience to users, but also improves the service efficiency. But no protection is made against information security.

Disclosure of Invention

The invention aims to at least solve the technical problems in the prior art, and particularly creatively provides a big data government affair analysis and processing safety application platform.

In order to achieve the above purpose, the invention provides a big data government affair analysis processing security application platform, which comprises a data acquisition module, a data processing and transmitting module and a data verification and display module;

the data acquisition module is used for acquiring user information;

the data processing and transmitting module is used for processing the user information acquired by the data acquisition module and transmitting the processed user information to the cloud platform;

and after the data verification display module is used for verifying the cloud platform, the data verification display module displays the data information corresponding to the user on the touch display screen.

In conclusion, due to the adoption of the technical scheme, the invention can play a protective role in government affair safety and avoid attack.

Additional aspects and advantages of the invention will be set forth in part in the description which follows and, in part, will be obvious from the description, or may be learned by practice of the invention.

Drawings

The above and/or additional aspects and advantages of the present invention will become apparent and readily appreciated from the following description of the embodiments, taken in conjunction with the accompanying drawings of which:

fig. 1 is a schematic block diagram of the present invention.

Fig. 2 is a schematic structural diagram of the present invention.

Detailed Description

Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to the accompanying drawings are illustrative only for the purpose of explaining the present invention, and are not to be construed as limiting the present invention.

The invention provides a big data government affair analysis processing safety application platform, which comprises a data acquisition module, a data processing and transmitting module and a data verification and display module, wherein the data acquisition module is used for acquiring and transmitting data;

the data acquisition module is used for acquiring user information;

and the data verification display module is used for displaying the data information corresponding to the user on the touch display screen 3 after the cloud platform verifies the data information.

In a preferred embodiment of the present invention, the data processing transmission module comprises the following steps:

s21, carrying out the following operation on the acquired user information to obtain an operation result value;

ORV＝MD(User Info)，

wherein, MD () represents a hashing algorithm using MD 5;

user Info represents User information, including one or any combination of identity card number, telephone number, license plate number;

ORV represents the operation result value;

s22, converting the operation result value ORV obtained in the step S21 into a B system, wherein B is a positive integer greater than or equal to 2, and obtaining the B system operation result;

judging whether the operation result value ORV is B system:

if the operation result value ORV is B system, then V_BORV; wherein ORV is the operation result value, V_BIs a B-system result value;

if the operation result value ORV is not B-scale, then steps S221-S222 are included;

s221, the operation result value ORV is converted into a C-ary result, and the preferred C-ary result is a 10-ary result. The method for converting the operation result value ORV into the C-system result comprises the following steps:

wherein < ORV > represents the total number of bits of the operation result value ORV;

ORV_arepresenting the numerical value corresponding to the a-th bit in the sequence from low to high of the operation result value ORV;

[A] representing a carry number corresponding to the operation result value ORV;

[A]^a-1is represented by [ A]To the power of a-1;

V_ORV→Cthe method comprises the steps of converting an operation result value ORV into a C-system result;

s222, carry the C to the result V_ORV→CConverting into B system operation result, and converting into C system result V_ORV→CThe method for converting the B-system operation result comprises the following steps:

s2221, setting the round-robin parameter i to 1; a is₁＝V_ORV→C；

Wherein int () represents a rounding function;

[B] representing a system value corresponding to the B system;

a_irepresenting the integral quantity of the ith cycle;

a_i+1represents the rounding amount of the i +1 th cycle;

determine a thereof_i+1And 0, [ B ]]-1 and [ B]The relationship between:

if a_i+1≥[B]I +1, returning to step S2222;

if 0 is less than or equal to a_i+1≤([B]-1), then comprising steps S22221 to S22222;

s22221, setting the cyclic remainder parameter j to 1;

S22222，b_j＝a_j％[B]，

wherein,% represents the remainder;

[B] representing a system value corresponding to the B system;

a_jrepresents the integer quantity of the j cycle;

b_jindicating that the jth cycle takes the margin;

judging the relationship between j and i:

if j ≠ i, j ≠ j +1, returning to S22132;

if j is i, then B is B_ib_i-1b_i-2…b₃b₂b₁(ii) a In this embodiment, b is defined as_QWhen the value is more than or equal to 10, Q is 1,2,3, …, i-2, i-1, i; 10, 11, 12, 13, 14, 15, … … and 35 can be sequentially represented by capital letters A, B, C, D, E, F, … … and Z; 36, 37, 38, 39, 40, 41, … …, 61 are indicated in turn by the lower case letters a, b, c, d, e, f, … …, z. Other values, if greater than or equal to 10, may be represented by the capital letters A, B, C, D, E, F, … …, Z in turn as 10, 11, 12, 13, 14, 15, … …, 35; 36, 37, 38, 39, 40, 41, … …, 61 are indicated in turn by the lower case letters a, b, c, d, e, f, … …, z.

Wherein { B } represents a B-system operation result;

b₁indicating that the 1 st cycle takes the allowance;

b₂indicating the 2 nd cycle allowance;

b₃indicating that the 3 rd cycle takes the allowance;

b_i-2indicating the residue taken in the i-2 th cycle;

b_i-1indicating that the cycle i-1 takes the residue;

b_iindicating the margin taken by the ith cycle;

s23, the result { B } of the B-system operation is counted from 0 to [ B ]]The number of-1, written as | | (0, u)₀),(1,u₁),(2,u₂),(3,u₃),…,([B]-1,u_[B]-1)||_{B}Wherein, the highest bit in the B system operation result { B } is not 0, namely the first bit is not 0; when it is a 1-bit number, only a 1-bit number can be written, for example, if it is 0, only 0 can be written, 00 cannot be written, or a plurality of 0's before or after 0; if 1, only 1 can be written, 01 cannot be written, or a plurality of 0 s precede 1.

Wherein (0, u)₀) Represents that the number of 0 s is u₀A, the u₀Is a positive integer greater than or equal to 0 and less than or equal to < B >; the { B } represents the total number of bits of the B scale operation result { B };

(1,u₁) The number of 1 s is u₁A, the u₁Is a positive integer greater than or equal to 0 and less than or equal to < B >;

(2,u₂) The number of 2 is u₂A, the u₂Is a positive integer greater than or equal to 0 and less than or equal to < B >;

(3,u₃) The number of the symbols 3 is u₃A, the u₃Is a positive integer greater than or equal to 0 and less than or equal to < B >;

([B]-1,u_[B]-1) Is represented by [ B]The number of-1 is u_[B]-1A, the u_[B]-1Is greater than or equal to 0 and less than or equal to<{B}>A positive integer of (d); u. of₀+u₁+u₂+u₃+…+u_[B]-1＝<{B}>；

S24, expressing the B-system number of the vector u₀u₁u₂u₃…u_[B]-1.[B]Or B-system number expression quantity u₀u₁u₂u₃…u_[B]-1Carrying out the following operations to obtain a first encryption result value; wherein the B-system number expression quantity u₀u₁u₂u₃…u_[B]-1.[B]Or u₀u₁u₂u₃…u_[B]-1Indicates u in B scale₀0, u ₁1, u ₂2, u ₃3, … …, u_[B]-1A (B)]-1. For example, a 2-ary number expression of 22.2 or 22 indicates 20 s and 21 s in a 2-ary expression; the corresponding 2-ary operation results may be 1010, 1001, 1100. The 2-ary number expression 02.2 or 02 indicates 0 s and 21 s (i.e., only 21 s) in the 2-ary expression; its corresponding 2-ary operation result may be 11. The 2-system number expression quantity 15.2 or 15 indicates that 10 and 5 1 exist in the 2-system expression; the corresponding 2-ary operation results may be 101111, 110111, 111011, 111101, 111110. The 3-system number expression quantity 120.3 or 120 indicates that 10, 21, 02 (only 10 and 2 1) are expressed in the 3-system; the corresponding 3-ary operation results may be 101, 110. The 3-system number expression quantity 111.3 or 111 indicates that 10, 1 and 12 exist in the 3-system expression; the corresponding 3-ary operation results may be 102, 120, 201, 210. The expression amount 1011.4 or 1011 of the 4-system number indicates 10, 01, 12, 13 (i.e. 10, 12, 1 3) in the 4-system expression; the corresponding 4-ary operation results may be 203, 230, 302, 320. The 4-ary numerical expression 1101.4 or 1101 indicates that 10, 1, 0, 2, 13 (i.e., 10, 1, 3) are expressed in 4-ary; the corresponding 4-ary operation results may be 103, 130, 301, 310. The 8-system number expression 00110010.8 or 00110010 indicates that 0, 01, 12, 13, 04, 05, 16, 07 (i.e. only 12, 13, 1 6) are expressed in the 0-system; the corresponding 8-ary operation result may be 236, 263, 326, 362, 623, 632. The 16-ary numerical expression 0000100000010001.16 or 0000100000010001 indicates that there are 0, 01, 02, 03, 14, 05, 06, 07, 0 8, 09, 0a, 1B, 0C, 0D, 0E, 1F (i.e., there are only 14, 1B, 1F) in the 16-ary expression; the corresponding 16-ary operation results may be 4BF, 4FB, B4F, BF4, F4B, and FB 4.

ERV＝MD(u₀u₁u₂u₃…u_[B]-1.[B])，

Wherein, MD () represents a hashing algorithm using MD 5;

u₀u₁u₂u₃…u_[B]-1.[B]expressing B-system number expression quantity;

ERV represents a first encryption result value;

and S25, sending the first encryption result value ERV to the cloud platform.

An example is given below, taking telephone numbers 13333333333, [ B ] 8, [ C ] 10 as an example:

firstly, obtaining an operation result value:

ORV ═ md (user info), i.e.

The ORV (13333333333) ═ MD (34347C 343003E57232A5D21F14FE399E, which is a 32-bit 16-ary operation result value.

Secondly, solving a 10-system result:

namely, it is

Thirdly, solving the value of i:

namely, it is

Since 0 is less than or equal to a₄₂Not more than 8-1, namely not less than 0 and not more than 6 and not more than 7; so i is 42.

Fourthly, solving the 8-system operation result:

b_j＝a_j％[B]i.e. by

b₂＝a₂％8

＝8674046796371841344243255013636294451％8，

＝3

b₃＝a₃％8

＝1084255849546480516803040676704536806％8，

＝6

……，

b₄₀＝a₄₀％8

＝417％8，

＝1

b₄₁＝a₄₁％8

＝52％8，

＝4

b₄₂＝a₄₂％8

＝6％8，

＝6

Since j-i, i.e., j-i-42,

then

Fifthly, counting the number of 0-7 in 641507606414001745344312456441742477434636, and recording as | | (0, u)₀),(1,u₁),(2,u₂),(3,u₃),…,([B]-1,u_[B]-1)||_{641507606414001745344312456441742477434636}I.e. by

Sixthly, obtaining a first encryption result value:

ERV＝MD(u₀u₁u₂u₃…u_[B]-1.[B])，

namely, it is

Seventhly, sending the B0DE35E8C50FCB14A7765B73C196A8AA to the cloud platform.

In a preferred embodiment of the present invention, in the data processing and transmitting module, the steps S22 to S25 are:

s22, converting the operation result value ORV obtained in the step S21 into a B ' system, wherein B ' is a positive integer greater than or equal to 2, and B ' ≠ B; obtaining the B' system operation result;

judging whether the operation result value ORV is B' system:

if the operation result value ORV is B' system, then V_B′ORV; wherein ORV is the operation result value, V_B′Is a B' scale result value;

if the operation result value ORV is not in the B' scale, the method includes steps S221-S222;

s221, the method of converting the operation result value ORV into the C-ary result includes:

[A]^a-1is represented by [ A]To the power of a-1;

s222, carry the C to the result V_ORV→CConverting into B' system operation result, and converting into C system result V_ORV→CThe method for converting the B' system operation result comprises the following steps:

s2221, rounding the loop to obtain a first parameter i' equal to 1; a is₁＝V_ORV→C；

S2222，

Wherein int () represents a rounding function;

[ B '] represents a scale value corresponding to the B' scale;

a_i′representing the ith' round up quantity;

a_i′+1represents the i' +1 cycle integer;

determine a thereof_i′+1And 0, [ B']-1 and [ B']The relationship between:

if a_i′+1≥[B′]I' +1, return to step S2222;

if 0 is less than or equal to a_i′+1≤([B′]-1), then comprising steps S22221 to S22222;

s22221, setting the cyclic residual first parameter j' to 1;

S22222，b_j′＝a_j′％[B′]，

wherein,% represents the remainder;

[ B '] represents a scale value corresponding to the B' scale;

a_j′represents the cycle integer of j';

b_j′represents the residue taken by the j' th cycle;

judging the relationship between j 'and i':

if j ' ≠ i ', j ' +1, returning to S22132;

if j ' is i ', then B ' is B_i′b_i′-1b_i′-2…b₃b₂b₁(ii) a In this embodiment, b is defined as_Q′When the value is more than or equal to 10, Q 'is 1,2,3, …, i' -2, i '-1, i'; 10, 11, 12, 13, 14, 15, … … and 35 can be sequentially represented by capital letters A, B, C, D, E, F, … … and Z; 36, 37, 38, 39, 40, 41, … …, 61 are indicated in turn by the lower case letters a, b, c, d, e, f, … …, z. Other values, if greater than or equal to 10, may be represented by the capital letters A, B, C, D, E, F, … …, Z in turn as 10, 11, 12, 13, 14, 15, … …, 35; 36, 37, 38, 39, 40, 41, … …, 61 are indicated in turn by the lower case letters a, b, c, d, e, f, … …, z.

Wherein, { B '} represents a B' system operation result;

b₁indicating that the 1 st cycle takes the allowance;

b₂indicating the 2 nd cycle allowance;

b₃indicating that the 3 rd cycle takes the allowance;

b_i′-2indicating the residue taken in the i' -2 th cycle;

b_i′-1indicating that the cycle i' -1 takes the rest;

b_i′indicating the i' th cycle allowance;

s23, counting 0 to [ B 'in B' system operation result { B '}']The number of-1, written as | | (0, u)₀′),(1,u₁′),(2,u₂′),(3,u₃′),…,([B′]-1,u_[B′]-1′)||_{B′}Wherein, the highest bit in the B 'system operation result { B' } is not 0, namely the first bit is not 0; when it is a 1-bit number, only a 1-bit number can be written, for example, if it is 0, only 0 can be written, 00 cannot be written, or a plurality of 0's before or after 0; if 1, it can only be usedWrite as a 1, cannot write as a 01, or precede a 1 by more than 0.

Wherein (0, u)₀') indicates that the number of 0 s is u₀' u, said u₀' is greater than or equal to 0 and less than or equal to<{B′}>A positive integer of (d);<{B′}>represents the total number of bits of the B 'system operation result { B' };

(1,u₁') indicates that the number of 1 s is u₁' u, said u₁' is greater than or equal to 0 and less than or equal to<{B′}>A positive integer of (d);

(2,u₂') indicates 2 is u₂' u, said u₂' is greater than or equal to 0 and less than or equal to<{B′}>A positive integer of (d);

(3,u₃') indicates that the number of 3 is u₃' u, said u₃' is greater than or equal to 0 and less than or equal to<{B′}>A positive integer of (d);

([B′]-1,u_[B′]-1') represents [ B']The number of-1 is u_[B′]-1' u, said u_[B]′-1' is greater than or equal to 0 and less than or equal to<{B′}>A positive integer of (d); u. of₀′+u₁′+u₂′+u₃′+…+u_[B′]-1′＝<{B′}<；

S24, expressing the B' number expression u₀′u₁′u₂′u₃′…u_[B′]-1′.[B′]Or u₀′u₁′u₂′u₃′…u_[B′]-1' get its second encryption result value; wherein B' is a number expression u₀′u₁′u₂′u₃′…u_[B′]-1′.[B′]Or u₀′u₁′u₂′u₃′…u_[B′]-1'indicates that there is u in B' scale₀' 0, u₁' pieces 1, u₂' pieces 2, u₃' pieces 3, … …, u_[B′]-1'A']-1. For example, a 2-ary number expression of 22.2 or 22 indicates 20 s and 21 s in a 2-ary expression; its corresponding 2-ary operationThe results may be 1010, 1001, 1100. The 2-ary number expression 02.2 or 02 indicates 0 s and 21 s (i.e., only 21 s) in the 2-ary expression; its corresponding 2-ary operation result may be 11. The 2-system number expression quantity 15.2 or 15 indicates that 10 and 5 1 exist in the 2-system expression; the corresponding 2-ary operation results may be 101111, 110111, 111011, 111101, 111110. The 3-system number expression quantity 120.3 or 120 indicates that 10, 21, 02 (only 10 and 2 1) are expressed in the 3-system; the corresponding 3-ary operation results may be 101, 110. The 3-system number expression quantity 111.3 or 111 indicates that 10, 1 and 12 exist in the 3-system expression; the corresponding 3-ary operation results may be 102, 120, 201, 210. The expression amount 1011.4 or 1011 of the 4-system number indicates 10, 01, 12, 13 (i.e. 10, 12, 1 3) in the 4-system expression; the corresponding 4-ary operation results may be 203, 230, 302, 320. The 4-ary numerical expression 1101.4 or 1101 indicates that 10, 1, 0, 2, 13 (i.e., 10, 1, 3) are expressed in 4-ary; the corresponding 4-ary operation results may be 103, 130, 301, 310. The 8-system number expression 00110010.8 or 00110010 indicates that 0, 01, 12, 13, 04, 05, 16, 07 (i.e. only 12, 13, 1 6) are expressed in the 0-system; the corresponding 8-ary operation result may be 236, 263, 326, 362, 623, 632. The 16-ary numerical expression 0000100000010001.16 or 0000100000010001 indicates that there are 0, 01, 02, 03, 14, 05, 06, 07, 0 8, 09, 0a, 1B, 0C, 0D, 0E, 1F (i.e., there are only 14, 1B, 1F) in the 16-ary expression; the corresponding 16-ary operation results may be 4BF, 4FB, B4F, BF4, F4B, and FB 4.

ERV′＝MD(u₀′u₁′u₂′u₃′…u_[B′]-1′.[B′])，

Wherein, MD () represents a hashing algorithm using MD 5;

u₀′u₁′u₂′u₃′…u_[B′]-1′.[B′]expressing B' system number expression quantity;

ERV' represents a second encryption result value;

and S25, sending the second encryption result value ERV' to the cloud platform.

An example is given below, taking the telephone number 13333333333, [ B' ] 16, [ C ] 10 as an example:

firstly, obtaining an operation result value:

ORV ═ md (user info), i.e.

Secondly, solving a 10-system result:

namely, it is

Thirdly, solving the value of i':

namely, it is

Since 0 is less than or equal to a₃₂Less than or equal to (16-1), namely less than or equal to 0 and less than or equal to 3 and less than or equal to 15; so i' is 32.

Fourthly, solving a 16-system operation result:

b_j′＝a_j′％[B′]i.e. by

b₂＝a₂％16

＝4337023398185920672121627506818147225％16，

＝9

b₃＝a₃％16

＝2710639623866200420076011594176134201％16，

＝9

……，

b₃₀＝a₃₀％16

＝835％16，

＝3

b₃₁＝a₃₁％16

＝52％16，

＝4

b₃₂＝a₃₂％16

＝3％16，

＝3

Since j 'is equal to i', i.e. j 'is equal to i' is equal to 32,

then

Fifthly, counting the number of 0-F in 34347C343003E57232A5D21F14FE399E, and recording the number as | | (0, u |)₀′),(1,u₁′),(2,u₂′),(3,u₃′),…,([B′]-1,u_[B′]-1′)||_{34347C343003E57232A5D21F14FE399E}I.e. by

Sixthly, obtaining a second encryption result value:

ERV′＝MD(u₀′u₁′u₂′u₃′…u_[B′]-1′.[B′]) I.e. by

ERV＝MD(2237420202101132.16)＝B2A509D26266599F38C799BF1599100A。

And seventhly, sending the B2A509D26266599F38C799BF1599100A to the cloud platform.

s22, converting the operation result value ORV obtained by the operation in the step S21 into a B 'system, wherein B' is a positive integer greater than or equal to 2, and B 'is not equal to B' ≠ B; obtaining the B' system operation result;

judging whether the operation result value ORV is B' system:

if the operation result value ORV is B' system, then V_B″ORV; wherein ORV is the operation result value, V_B″Is the B' scale result value;

if the operation result value ORV is not B' system, then it includes steps S221-S222;

[A]^a-1is represented by [ A]To the power of a-1;

s222, carry the C to the result V_ORV→CConverting into B' system operation result, and converting into C system result V_ORV→CThe method for converting the binary operation result into the B' system operation result comprises the following steps:

s2221, rounding the second parameter i ″, to 1; a is₁＝V_ORV→C；

S2222，

Wherein int () represents a rounding function;

[ B "] represents a scale value corresponding to the B";

a_i″represents the integral quantity of the i' cycle;

a_i″+1represents the i' +1 cycle rounding amount;

determine a thereof_i″+1And 0, [ B "]]-1 and [ B]The relationship between:

if a_i″+1≥[B″]I ″ +1, return to step S2222;

if 0 is less than or equal to a_i″+1≤([B″]-1), then comprising steps S22221 to S22222;

s22221, setting the cyclic remainder second parameter j ″, to 1;

S22222，b_j″＝a_j″％[B″]，

wherein,% represents the remainder;

[ B "] represents a scale value corresponding to the B";

a_j″represents the integer quantity of the j' cycle;

b_j″indicating that the j' cycle takes the surplus;

judging the relationship between j 'and i':

if j ≠ i ″, then j ≠ j ″ +1, returning to S22132;

if j ″ ═ i ″, then { B ″ } ═ B ″_i″b_i″-1b_i″-2…b₃b₂b₁(ii) a In this embodiment, b is defined as_Q″No less than 10, Q ″, 1,2,3,.., i "-2, i" -1, i "; 10, 11, 12, 13, 14, 15, … … and 35 can be sequentially represented by capital letters A, B, C, D, E, F, … … and Z; 36, 37, 38, 39, 40, 41, … …, 61 are indicated in turn by the lower case letters a, b, c, d, e, f, … …, z. Other values, if greater than or equal to 10, may be represented by the capital letters A, B, C, D, E, F, … …, Z in turn as 10, 11, 12, 13, 14, 15, … …, 35; 36, 37, 38, 39, 40, 41, … …, 61 are indicated in turn by the lower case letters a, b, c, d, e, f, … …, z.

Wherein, { B "} denotes the B" system operation result;

b₁indicating that the 1 st cycle takes the allowance;

b₂indicating the 2 nd cycle allowance;

b₃indicating that the 3 rd cycle takes the allowance;

b_i″-2represents the i' -2 cycle allowance;

b_i″-1represents the i' -1 th cycle to take the margin;

b_i″indicating that the ith' cycle takes the residue;

s23, counting 0 to [ B "] in B 'system operation result { B' }]The number of-1, written as | | (0, u)₀″),(1,u₁″),(2,u₂″),(3,u₃″),…,([B″]-1,u_[B″]-1″)||_{B″}Wherein, the highest bit in the B 'system operation result { B' } is not 0, i.e. the first bit is not 0; when it is a 1-bit number, only a 1-bit number can be written, for example, if it is 0, only 0 can be written, 00 cannot be written, or a plurality of 0's before or after 0; if 1, only 1 can be written, 01 cannot be written, or a plurality of 0 s precede 1.

Wherein (0, u)₀") indicates that the number of 0 s is u₀"to, said u₀Is greater than or equal to 0 and less than or equal to<{B″}>A positive integer of (d);<{B″}>representing B' binary operationsThe total number of bits of the result { B "};

(1,u₁") indicates that the number of 1 s is u₁"to, said u₁Is greater than or equal to 0 and less than or equal to<{B″}>A positive integer of (d);

(2,u₂") indicates that the number of 2 is u₂"to, said u₂Is greater than or equal to 0 and less than or equal to<{B″}>A positive integer of (d);

(3,u₃") indicates that the number of 3 is u₃"to, said u₃Is greater than or equal to 0 and less than or equal to<{B″}>A positive integer of (d);

([B″]-1,u_[B″]-1") means [ B]The number of-1 is u_[B″]-1"to, said u_[B″]-1"is a positive integer greater than or equal to 0 and less than or equal to < B'; u. of₀″+u₁″+u₂″+u₃″+…+u_[B″]-1″＝〈{B″}〉；

S24, expressing the B' number of the expression vector u₀″u₁″u₂″u₃″…u_[B″]-1″.[B″]Or u₀″u₁″u₂″u₃″…u_[B″]-1"perform the following operation to obtain a third encryption result value thereof; wherein B' is a number expression u₀″u₁″u₂″u₃″…u_[B″]-1″.[B″]Or u₀″u₁″u₂″u₃″…u_[B″]-1"indicates that there is u in the B" scale expression₀"each 0, u₁"each 1, u₂"an 2, u₃"each 3, … …, u_[B″]-1' A]-1. For example, a 2-ary number expression of 22.2 or 22 indicates 20 s and 21 s in a 2-ary expression; the corresponding 2-ary operation results may be 1010, 1001, 1100. The 2-ary number expression 02.2 or 02 indicates 0 s and 21 s (i.e., only 21 s) in the 2-ary expression; its corresponding 2-ary operation result may be 11. The 2-system number expression quantity 15.2 or 15 indicates that 10 and 5 1 exist in the 2-system expression; the corresponding 2-system operation result may be 101111, 110111. 111011, 111101 and 111110. The 3-system number expression quantity 120.3 or 120 indicates that 10, 21, 02 (only 10 and 2 1) are expressed in the 3-system; the corresponding 3-ary operation results may be 101, 110. The 3-system number expression quantity 111.3 or 111 indicates that 10, 1 and 12 exist in the 3-system expression; the corresponding 3-ary operation results may be 102, 120, 201, 210. The expression amount 1011.4 or 1011 of the 4-system number indicates 10, 01, 12, 13 (i.e. 10, 12, 1 3) in the 4-system expression; the corresponding 4-ary operation results may be 203, 230, 302, 320. The 4-ary numerical expression 1101.4 or 1101 indicates that 10, 1, 0, 2, 13 (i.e., 10, 1, 3) are expressed in 4-ary; the corresponding 4-ary operation results may be 103, 130, 301, 310. The 8-system number expression 00110010.8 or 00110010 indicates that 0, 01, 12, 13, 04, 05, 16, 07 (i.e. only 12, 13, 1 6) are expressed in the 0-system; the corresponding 8-ary operation result may be 236, 263, 326, 362, 623, 632. The 16-ary numerical expression 0000100000010001.16 or 0000100000010001 indicates that there are 0, 01, 02, 03, 14, 05, 06, 07, 0 8, 09, 0a, 1B, 0C, 0D, 0E, 1F (i.e., there are only 14, 1B, 1F) in the 16-ary expression; the corresponding 16-ary operation results may be 4BF, 4FB, B4F, BF4, F4B, and FB 4.

ERV″＝MD(u₀″u₁″u₂″u₃″…u_[B″]-1″.[B″])，

Wherein, MD () represents a hashing algorithm using MD 5;

u₀″u₁″u₂″u₃″…u_[B″]-1″.[B″]representing the expression quantity of the B' system number;

ERV "represents a third encryption result value;

and S25, sending the third encryption result value ERV' to the cloud platform.

In a preferred embodiment of the present invention, the data verification display module comprises the following steps:

s31, the cloud platform receives according to the dataInquiring the first encryption result value ERV and the second encryption result value ERV 'to obtain a cloud platform storage first value corresponding to the first encryption result value ERV and a cloud platform storage second value corresponding to the second encryption result value ERV'; namely, the first encryption result value ERV and the second encryption result value ERV' belong to the cloud platform encryption result set; the first value stored by the cloud platform corresponding to the first encryption result value ERV is equivalent to the element e in the cloud platform encryption result set₁The corresponding cloud platform expression quantity, the second value stored by the cloud platform corresponding to the second encryption result value ERV' is equivalent to the element e in the cloud platform encryption result set₂The corresponding cloud platform expression quantity.

S32, calculating according to the first value stored by the cloud platform and the second value stored by the cloud platform to obtain a first set of cloud platform combination values corresponding to the first value stored by the cloud platform and a second set of cloud platform combination values corresponding to the second value stored by the cloud platform;

judging whether the first set of the cloud platform combination values and the second set of the cloud platform combination values have equal actual values:

if the first set of cloud platform combined values and the second set of cloud platform combined values have equal actual values, inquiring to obtain user information according to the actual values, and executing step S33;

if the first set of the cloud platform combined value and the second set of the cloud platform combined value do not have equal actual values, the first encryption result value ERV and the second encryption result value ERV' are received again;

and S33, transmitting the data information corresponding to the user to the display terminal for displaying.

s31, the cloud platform queries according to the received first encryption result value ERV, the second encryption result value ERV 'and the third encryption result value ERV' to obtain a first value stored by the cloud platform corresponding to the first encryption result value ERV, a second value stored by the cloud platform corresponding to the second encryption result value ERV 'and a third value stored by the cloud platform corresponding to the third encryption result value ERV'; i.e. the first encryption result value ERV, the secondThe second encryption result value ERV 'and the third encryption result value ERV' both belong to the cloud platform encryption result set, and the first value stored by the cloud platform corresponding to the first encryption result value ERV is equivalent to the element e in the cloud platform encryption result set₁The corresponding cloud platform expression quantity, the second value stored by the cloud platform corresponding to the second encryption result value ERV' is equivalent to the element e in the cloud platform encryption result set₂The corresponding cloud platform expression quantity and the third value stored by the cloud platform corresponding to the third encryption result value ERV' are equivalent to the element e in the cloud platform encryption result set₃The corresponding cloud platform expression quantity.

S32, calculating according to the first value stored by the cloud platform, the second value stored by the cloud platform and the third value stored by the cloud platform to obtain a first set of cloud platform combination values corresponding to the first value stored by the cloud platform, a second set of cloud platform combination values corresponding to the second value stored by the cloud platform and a third set of cloud platform combination values corresponding to the third value stored by the cloud platform; in this embodiment, for example, if the cloud platform expression amount (the cloud platform storage first value) is 14.2 or 14, it indicates that there are 10 and 41 in the 2-system expression, and the elements in the first set of cloud platform combination values corresponding to the cloud platform storage first value are 1011, 1101, 1110; if the cloud platform expression quantity (the second value stored by the cloud platform) is 00020000.8 or 00020000, it indicates that there are only 23 in the 8-system expression, and the element in the second set of the cloud platform combination value corresponding to the second value stored by the cloud platform is 33; if the cloud platform expression amount (the cloud platform stores the third value) is 0111.4 or 0111, it indicates that there are 1,2, and 1, 3 in the 4-ary expression, and the elements in the third set of the cloud platform combination value corresponding to the cloud platform storing the third value are 123, 132, 213, 231, 312, and 321.

Judging whether the first set of the cloud platform combination values, the second set of the cloud platform combination values and the third set of the cloud platform combination values have equal actual values:

if the first set of cloud platform combined values, the second set of cloud platform combined values and the third set of cloud platform combined values have equal actual values (the actual values are values under the condition that the system is the same), inquiring according to the actual values to obtain user information, and executing step S33; in this embodiment, for example, if the cloud platform expression level (the cloud platform storage first value) is 14.2 or 14, it indicates that there are 10 and 41 in the 2-system expression, and the elements in the first set of cloud platform combination values corresponding to the cloud platform storage first value are 10111, 11011, 11101, 11110; if the cloud platform expression quantity (the second value stored by the cloud platform) is 00020000.8 or 00020000, it indicates that there are only 23 in the 8-system expression, and the element in the second set of the cloud platform combination value corresponding to the second value stored by the cloud platform is 33; if the cloud platform expression amount (the cloud platform stores the third value) is 0111.4 or 0111, it indicates that there are 1,2, and 1, 3 in the 4-ary expression, and the elements in the third set of the cloud platform combination value corresponding to the cloud platform storing the third value are 123, 132, 213, 231, 312, and 321. Converting the 2-system values in the first set of cloud platform combined values into 10-system values which are 23, 27, 29 and 30 in sequence; converting the 8-system values in the second set of the cloud platform combined values into 10-system values, and sequentially corresponding to the 10-system values to be 27; the 4-system values in the third set of cloud platform combined values are converted into 10-system values, and the values are 27, 30, 39, 45, 54 and 57 in sequence. Since there are equal actual values 27 in the first set of cloud platform combined values, the second set of cloud platform combined values, and the third set of cloud platform combined values. Converting the 2-system values in the first set of cloud platform combined values into 16-system values which are respectively 17, 1B, 1D and 1E; converting the 8-system values in the second set of the cloud platform combined values into 16-system values, and sequentially corresponding to 1B; and converting the 4-system values in the third set of the cloud platform combined values into 16-system values which are sequentially corresponding to 1B, 1E, 27, 2D, 36 and 39. The first set of cloud platform combined values, the second set of cloud platform combined values, and the third set of cloud platform combined values have equal actual values 1B.

If the first set of the cloud platform combined value, the second set of the cloud platform combined value and the third set of the cloud platform combined value do not have equal actual values, the first encryption result value ERV, the second encryption result value ERV 'and the third encryption result value ERV' are received again;

In a preferred embodiment of the present invention, a data pre-storing module is included before the data acquiring module, and is used for storing the processed data in a database for query; the data pre-storing module comprises the following steps:

s01, the cloud platform carries out the following operations on the acquired user information to obtain the cloud platform operation result value;

ORV″′＝MD(User Info″′)，

wherein, MD () represents a hashing algorithm using MD 5;

the User Info' ″ represents User information acquired by the cloud platform, and comprises one or any combination of an identity card number, a telephone number and a license plate number;

ORV' "represents the cloud platform operation result value;

s02, converting the cloud platform operation result value ORV '"obtained by operation in the step S01 into a B'" system, wherein B '"is a positive integer greater than or equal to 2, and obtaining the B'" system cloud platform operation result;

judging whether the cloud platform operation result value ORV 'is in a B' scale or not:

if the cloud platform operation result value ORV 'is in the B' system, then V_B″′ORV "; wherein ORV' is the cloud platform operation result value, V_B″′B' is a cloud platform result value;

if the cloud platform operation result value ORV 'is not in the B' system, the method comprises the steps of S021S 022;

s021, converting the cloud platform operation result value ORV 'into a C' system cloud platform result, and converting the cloud platform operation result value ORV 'into the C' system cloud platform result, wherein the method comprises the following steps:

wherein < ORV '"> represents the total number of bits of the cloud platform operation result value ORV'";

ORV″′_a″representing the a '"bit in the cloud platform operation result value ORV'" ordered from low to highThe corresponding numerical value;

[ A '] represents a binary value corresponding to the cloud platform operation result value ORV';

[A″′]^a″′-1is represented by [ A']A' "-1 to the power of;

V_{ORV″′→C″′}representing the conversion of its cloud platform operation result value ORV '"to a C'" binary cloud platform result;

s022, carrying out C' system on the cloud platform result V_{ORV″′→C″′}Converting into B 'system cloud platform operation result, and converting into C' system cloud platform result V_{ORV″′→C″′}The method for converting the B' system cloud platform operation result comprises the following steps:

s0221, enabling a circulating rounding cloud platform parameter i' to be 1; a is₁″′＝V_{ORV″′→C″′}；

S0222，

Wherein int () represents a rounding function;

[ B '"] indicates a scale value corresponding to the B'" scale;

a_i″"'indicates the i' cycle to round the cloud platform amount;

a_i″′+1"'indicates the i' +1 cycle to round the cloud platform volume;

determine a thereof_i″′+1"'and 0, [ B']-1 and [ B']The relationship between:

if a_i″′+1″′≥[B″′]I "" +1, return to step S0222;

if 0 is less than or equal to a_i″′+1″′≤([B″′]-1), then comprising steps S02221 to S02222;

s02221, enabling a circulating residual cloud platform parameter j' to be 1;

S02222，b_j″″′＝a_j″″′％[B″′]，

wherein,% represents the remainder;

[ B '"] indicates a scale value corresponding to the B'" scale;

a_j″"'indicates the j' cycle rounding cloud platform quantity;

b_j″"'indicates the j'" th cycle surplus cloud platform amount;

judging the relationship between j 'and i':

if j '≠ i' ″, j '″ is j' ″ +1, and the process returns to S22132;

if j 'is i', then B '} is B'_i″″′b_i″′-1″′b_i″′-2″′…b₃″′b₂″′b₁"; in this embodiment, b is defined as_Q″When "≧ 10, Q '" 1,2,3,., i' "-2, i '" -1, i' "; 10, 11, 12, 13, 14, 15, … … and 35 can be sequentially represented by capital letters A, B, C, D, E, F, … … and Z; 36, 37, 38, 39, 40, 41, … …, 61 are indicated in turn by the lower case letters a, b, c, d, e, f, … …, z. Other values, if greater than or equal to 10, may be represented by the capital letters A, B, C, D, E, F, … …, Z in turn as 10, 11, 12, 13, 14, 15, … …, 35; 36, 37, 38, 39, 40, 41, … …, 61 are indicated in turn by the lower case letters a, b, c, d, e, f, … …, z.

Wherein { B '} represents a B' system cloud platform operation result;

b₁"' indicates the residual cloud platform quantity obtained in the 1 st cycle;

b₂"' indicates the residual cloud platform quantity of the 2 nd cycle;

b₃"' indicates the residual cloud platform quantity of the 3 rd cycle;

b_i″′-2"'indicates the i' -2 loop residual cloud platform amount;

b_i″′-1"'indicates the i' -1 cycle residual cloud platform amount;

b_i″"'indicates the i' cycle residual cloud platform amount;

s03, statistics are carried out on 0 to [ B '″) in the B' ″ system cloud platform operation result { B '″ }']The number of-1, written as | | (0, u)₀″′),(1,u₁″′),(2,u₂″′),(3,u₃″′),…,([B″′]-1,u_[B″′]-1″′)||_{B″′}Wherein, the highest bit in the B 'carry operation result { B' } is not 0, i.e. the first bit is not 0; when it is a 1-bit number, only a 1-bit number can be written, for example, if it is 0, only 0 can be written, 00 cannot be written, or a plurality of 0's before or after 0; if 1, only 1 can be written, 01 cannot be written, or a plurality of 0 s precede 1.

Wherein (0, u)₀") indicates that the number of 0 s is u₀", said u₀"' is greater than or equal to 0 and less than or equal to<{B″′}>A positive integer of (d);<{B″′}>a total number of bits representing a B 'binary cloud platform operation result { B' };

(1,u₁") indicates that the number of 1 s is u₁", said u₁"' is greater than or equal to 0 and less than or equal to<{B″′}>A positive integer of (d);

(2,u₂") indicates that the number of 2 is u₂", said u₂"' is greater than or equal to 0 and less than or equal to<{B″′}>A positive integer of (d);

(3,u₃") indicates that the number of 3 is u₃", said u₃"' is greater than or equal to 0 and less than or equal to<{B″′}>A positive integer of (d);

([B″′]-1,u_[B″′]-1") represents [ B"']The number of-1 is u_[B″′]-1", said u_[B″′]-1"' is greater than or equal to 0 and less than or equal to<{B″′}>A positive integer of (d); u. of₀″′+u₁″′+u₂″′+u₃″′+…+u_[B″′]-1″′＝<{B″′}>；

S04, expressing the B' number cloud platform expression u₀″′u₁″′u₂″′u₃″′…u_[B″′]-1″′.[B″′]Or u₀″′u₁″′u₂″′u₃″′…u_[B″′]-1"' the following operations are carried outObtaining an encryption result value of the cloud platform; wherein B' is a number expressed in u₀″′u₁″′u₂″′u₃″′…u_[B″′]-1″′.[B″′]Or u₀″′u₁″′u₂″′u₃″′…u_[B″′]-1"'indicates that there is u in the B' scale expression₀"' one 0, u₁"' one 1, u₂"' 2, u₃"' one 3, … …, u_[B″′]-1"'pieces of [ B']-1. For example, a 2-ary number expression of 22.2 or 22 indicates 20 s and 21 s in a 2-ary expression; the corresponding 2-ary operation results may be 1010, 1001, 1100. The 2-ary number expression 02.2 or 02 indicates 0 s and 21 s (i.e., only 21 s) in the 2-ary expression; its corresponding 2-ary operation result may be 11. The 2-system number expression quantity 15.2 or 15 indicates that 10 and 5 1 exist in the 2-system expression; the corresponding 2-ary operation results may be 101111, 110111, 111011, 111101, 111110. The 3-system number expression quantity 120.3 or 120 indicates that 10, 21, 02 (only 10 and 2 1) are expressed in the 3-system; the corresponding 3-ary operation results may be 101, 110. The 3-system number expression quantity 111.3 or 111 indicates that 10, 1 and 12 exist in the 3-system expression; the corresponding 3-ary operation results may be 102, 120, 201, 210. The expression amount 1011.4 or 1011 of the 4-system number indicates 10, 01, 12, 13 (i.e. 10, 12, 1 3) in the 4-system expression; the corresponding 4-ary operation results may be 203, 230, 302, 320. The 4-ary numerical expression 1101.4 or 1101 indicates that 10, 1, 0, 2, 13 (i.e., 10, 1, 3) are expressed in 4-ary; the corresponding 4-ary operation results may be 103, 130, 301, 310. The 8-system number expression 00110010.8 or 00110010 indicates that 0, 01, 12, 13, 04, 05, 16, 07 (i.e. only 12, 13, 1 6) are expressed in the 0-system; the corresponding 8-ary operation result may be 236, 263, 326, 362, 623, 632. The 16-ary numerical expression 0000100000010001.16 or 0000100000010001 indicates that there are 0, 01, 02, 03, 14, 05, 06, 07, 0 8, 09, 0A, 1B, 0C, 0A in 16-ary expressionD, 0E, 1F (i.e. only 14, 1B, 1F); the corresponding 16-ary operation results may be 4BF, 4FB, B4F, BF4, F4B, and FB 4.

ERV″′＝MD(u₀″′u₁″′u₂″′u₃″′…u_[B″′]-1″′.[B″′])，

Wherein, MD () represents a hashing algorithm using MD 5;

u₀″′u₁″′u₂″′u₃″′…u_[B″′]-1″′.[B″′]representing B' system number cloud platform expression quantity;

ERV' "represents a cloud platform encryption result value;

and S05, forming a cloud platform encryption result set by all the cloud platform encryption result values ERV 'of the cloud platform encryption result set, storing the cloud platform encryption result set and the cloud platform expression quantity corresponding to each element in the cloud platform encryption result set in a cloud platform database, and storing the user information corresponding to the B' system cloud platform operation result in the cloud platform database.

The invention also discloses an application device of the big data government affair analysis processing safety application platform, which comprises a box body 5, wherein the front surface of the box body 5 is provided with an inward concave space, the concave space is provided with a touch display screen mounting seat for fixedly mounting a touch display screen 3, the touch display screen 3 is fixedly mounted on the touch display screen mounting seat, the lower side of the concave space is provided with an ID card reader mounting seat for fixedly mounting an ID card reader 4, the ID card reader 4 is fixedly mounted on the ID card reader mounting seat, two sides of the front surface of the box body 5 are provided with outward convex peep-proof plates 6, the box body 5 is internally provided with a control circuit board mounting seat for fixedly mounting a control circuit board, the control circuit board is fixedly mounted on the control circuit board mounting seat, the control circuit board is provided with a controller and a network transmission module, the network transmission data end of the controller is connected with the network transmission data end of the network transmission module, the identity information data output end of the identity ID card reader 4 is connected with the identity information data input end of the controller, and the touch display end of the controller is connected with the touch display end of the touch display screen 3;

and after the identity ID card reader 4 reads the user information, the user information is processed and then transmitted to the cloud platform for verification, and the data information corresponding to the user is called and displayed on the touch display screen 3.

In a preferred embodiment of the present invention, the network transmission module includes a network wireless transmission unit or/and a network wired transmission unit;

the wireless data end of the network wireless transmission unit is connected with the wireless data end of the controller, and the wired data end of the network wired transmission unit is connected with the wired data end of the controller;

the network wireless transmission unit comprises one or any combination of a network wireless WiFi transmission subunit, a network wireless 5G transmission subunit and a network wireless 4G transmission subunit;

the wireless WiFi data end of the network wireless WiFi transmission subunit is connected with the wireless WiFi data end of the controller, the wireless 5G data end of the network wireless 5G transmission subunit is connected with the wireless 5G data end of the controller, and the wireless 4G data end of the network wireless 4G transmission subunit is connected with the wireless 4G data end of the controller;

the network wired transmission unit comprises a hundred-megabyte network wired transmission subunit or/and a gigabit network wireless transmission subunit; the giga-cable data end of the giga-network cable transmission unit is connected with the giga-cable data end of the controller.

In a preferred embodiment of the present invention, the mobile phone further includes a camera fixing and mounting area which is arranged on the front surface of the box body 5 and is used for fixedly mounting the camera 1, and the camera 1 is fixedly mounted on the camera fixing and mounting area; the camera 1 is positioned above the touch display screen 3; the image data output end of the camera 1 is connected with the image data input end of the controller.

In a preferred embodiment of the present invention, the mobile phone further includes a peep-proof lens fixing and mounting area which is arranged on the front surface of the box body 5 and used for fixing the peep-proof lens 2, wherein the peep-proof lens 2 is positioned above the touch display screen 3 and on the left side or the right side of the camera 1; the sight-proof glass 2 is fixedly arranged on the sight-proof glass fixing and mounting area.

While embodiments of the invention have been shown and described, it will be understood by those of ordinary skill in the art that: various changes, modifications, substitutions and alterations can be made to the embodiments without departing from the principles and spirit of the invention, the scope of which is defined by the claims and their equivalents.

Claims

1. A big data government affair analysis processing safety application platform is characterized by comprising a data acquisition module, a data processing transmission module and a data verification display module;

the data acquisition module is used for acquiring user information;

2. The big data government affairs analysis and processing safety application platform according to claim 1, wherein the data processing transmission module comprises the following steps:

ORV＝MD(User Info)，

wherein, MD () represents a hashing algorithm using MD 5;

ORV represents the operation result value;

judging whether the operation result value ORV is B system:

if the operation result value ORV is B scale, then V_BORV; wherein ORV is the operation result value, V_BIs a B-system result value;

[A]^a-1is represented by [ A]To the power of a-1;

s2221, setting the round-robin parameter i to 1; a is₁＝V_ORV→C；

S2222，

Wherein int () represents a rounding function;

[B] representing a system value corresponding to the B system;

a_irepresenting the integral quantity of the ith cycle;

a_i+1represents the rounding amount of the i +1 th cycle;

determine a thereof_i+1And 0, [ B ]]-1 and [ B]The relationship between:

if a_i+1≥[B]I +1, returning to step S2222;

s22221, setting the cyclic remainder parameter j to 1;

S22222，b_j＝a_j％[B]，

wherein,% represents the remainder;

[B] representing a system value corresponding to the B system;

a_jrepresents the integer quantity of the j cycle;

b_jindicating that the jth cycle takes the margin;

judging the relationship between j and i:

if j ≠ i, j ≠ j +1, returning to S22132;

if j is i, then B is B_ib_i-1b_i-2…b₃b₂b₁；

Wherein { B } represents a B-system operation result;

b₁indicating that the 1 st cycle takes the allowance;

b₂indicating the 2 nd cycle allowance;

b₃indicating that the 3 rd cycle takes the allowance;

b_i-2indicating the residue taken in the i-2 th cycle;

b_i-1indicating that the cycle i-1 takes the residue;

b_iindicating the margin taken by the ith cycle;

s23, the result { B } of the B-system operation is counted from 0 to [ B ]]The number of-1, written as | | (0, u)₀),(1,u₁),(2,u₂),(3,u₃),…,([B]-1,u_[B]-1)||_{B}，

Wherein (0, u)₀) Represents that the number of 0 s is u₀A, the u₀Is greater than or equal to 0 and less than or equal to<{B}>-1 is a positive integer;<{B}>representing the total number of bits of the B-system operation result { B };

(1,u₁) The number of 1 s is u₁A, the u₁Is greater than or equal to 0 and less than or equal to<{B}>A positive integer of (d);

(2,u₂) The number of 2 is u₂A, the u₂Is greater than or equal to 0 and less than or equal to<{B}>A positive integer of (d);

(3,u₃) The number of the symbols 3 is u₃A, the u₃Is greater than or equal to 0 and less than or equal to<{B}>A positive integer of (d);

S24, expressing the B-system number of the vector u₀u₁u₂u₃…u_[B]-1.[B]Carrying out the following operations to obtain a first encryption result value;

ERV＝MD(u₀u₁u₂u₃…u_[B]-1.[B])，

wherein, MD () represents a hashing algorithm using MD 5;

u₀u₁u₂u₃…u_[B]-1.[B]expressing B-system number expression quantity;

ERV represents a first encryption result value;

and S25, sending the first encryption result value ERV to the cloud platform.

3. The big data government affair analysis and processing safety application platform according to claim 2, wherein in the data processing and transmission module, the steps S22-S25 are as follows:

judging whether the operation result value ORV is B' system:

[A]^a-1is represented by [ A]To the power of a-1;

S2222，

Wherein int () represents a rounding function;

[ B '] represents a scale value corresponding to the B' scale;

a_i′representing the ith' round up quantity;

a_i′+1represents the i' +1 cycle integer;

determine a thereof_i′+1And 0, [ B']-1 and [ B']The relationship between:

if a_i′+1≥[B′]I' +1, return to step S2222;

s22221, setting the cyclic residual first parameter j' to 1;

S22222，b_j′＝a_j′％[B′]，

wherein,% represents the remainder;

[ B '] represents a scale value corresponding to the B' scale;

a_j′represents the cycle integer of j';

b_j′represents the residue taken by the j' th cycle;

judging the relationship between j 'and i':

if j ' ≠ i ', j ' +1, returning to S22132;

if j ' is i ', then B ' is B_i′b_i′-1b_i′-2…b₃b₂b₁；

Wherein, { B '} represents a B' system operation result;

b₁indicating that the 1 st cycle takes the allowance;

b₂indicating the 2 nd cycle allowance;

b₃indicating that the 3 rd cycle takes the allowance;

b_i′-2indicating the residue taken in the i' -2 th cycle;

b_i′-1indicating that the cycle i' -1 takes the rest;

b_i′indicating the i' th cycle allowance;

s23, counting 0 to [ B 'in B' system operation result { B '}']The number of-1, written as | | (0, u)₀′),(1,u₁′),(2,u₂′),(3,u₃′),…,([B′]-1,u_[B′]-1′)||_{B′}，

Wherein (0, u)₀') indicates that the number of 0 s is u₀' u, said u₀' is greater than or equal to 0 and less than or equal to<{B′}>-1 is a positive integer;<{B′}>represents the total number of bits of the B 'system operation result { B' };

(1,u₁') indicates that the number of 1 s is u₁' u, said u₁' is greater than or equal to 0 and less than or equal to<Positive integer of { B' };

(3,u₃') indicates that the number of 3 is u₃' u, said u₃' is greater than or equal to 0 and less than or equal to<Positive integer of { B' };

([B′]-1,u_[B′]-1') represents [ B']The number of-1 is u_[B′]-1' u, said u_[B]′-1' is greater than or equal to 0 and less than or equal to<{B′}>A positive integer of (d); u. of₀′+u₁′+u₂′+u₃′+…+u_[B′]-1′＝〈{B′}〉；

S24, expressing the B' number expression u₀′u₁′u₂′u₃′…u_[B′]-1′.[B′]Carrying out the following operations to obtain a second encryption result value;

ERV′＝MD(u₀′u₁′u₂′u₃′…u_[B′]-1′.[B′])，

wherein, MD () represents a hashing algorithm using MD 5;

ERV' represents a second encryption result value;

and S25, sending the second encryption result value ERV' to the cloud platform.

4. The big data government affair analysis and processing safety application platform according to claim 2, wherein in the data processing and transmission module, the steps S22-S25 are as follows:

judging whether the operation result value ORV is B' system:

if the operation result value ORV is BCarry the system, then V_B″ORV; wherein ORV is the operation result value, V_B″Is the B' scale result value;

wherein < ORV > represents the total number of digits of the operation result value ORV;

[A]^a-1is represented by [ A]To the power of a-1;

s2221, rounding the second parameter i ″, to 1; a is₁＝V_ORV→C；

S2222，

Wherein int () represents a rounding function;

[ B "] represents a scale value corresponding to the B";

a_i″represents the integral quantity of the i' cycle;

a_i″+1represents the i' +1 cycle rounding amount;

determine a thereof_i″+1And 0, [ B "]]-1 and [ B]The relationship between:

if a_i″+1≥[B″]，iReturning to step S2222 when "+ 1";

s22221, setting the cyclic remainder second parameter j ″, to 1;

S22222，b_j″＝a_j″％[B″]，

wherein,% represents the remainder;

[ B "] represents a scale value corresponding to the B";

a_j″represents the integer quantity of the j' cycle;

b_j″indicating that the j' cycle takes the surplus;

judging the relationship between j 'and i':

if j ≠ i ″, then j ≠ j ″ +1, returning to S22132;

if j ″ ═ i ″, then { B ″ } ═ B ″_i″b_i″-1b_i″-2…b₃b₂b₁；

Wherein, { B "} denotes the B" system operation result;

b₁indicating that the 1 st cycle takes the allowance;

b₂indicating the 2 nd cycle allowance;

b₃indicating that the 3 rd cycle takes the allowance;

b_i″-2represents the i' -2 cycle allowance;

b_i″-1represents the i' -1 th cycle to take the margin;

b_i″indicating that the ith' cycle takes the residue;

s23, counting 0 to [ B "] in B 'system operation result { B' }]The number of-1, written as | | (0, u)₀″),(1,u₁″),(2,u₂″),(3,u₃″),…,([B″]-1,u_[B″]-1″)||_{B″}，

Wherein (0, u)₀") indicates that the number of 0 s is u₀"to, said u₀Is greater than or equal to 0 and less than or equal to<{B″}>-1 is a positive integer;<{B″}>represents the total number of bits of the B 'system operation result { B' };

([B″]-1,u_[B″]-1") means [ B]The number of-1 is u_[B″]-1"to, said u_[B″]-1Is greater than or equal to 0 and less than or equal to<{B″}>A positive integer of (d); u. of₀″+u₁″+u₂″+u₃″+…+u_[B″]-1″＝<{B″}>；

S24, expressing the B' number of the expression vector u₀″u₁″u₂″u₃″…u_[B″]-1″.[B″]Carrying out the following operations to obtain a third encryption result value;

ERV″＝MD(u₀″u₁″u₂″u₃″…u_[B″]-1″.[B″])，

wherein, MD () represents a hashing algorithm using MD 5;

ERV "represents a third encryption result value;

and S25, sending the third encryption result value ERV' to the cloud platform.

5. The big data government affairs analysis processing safety application platform according to claim 1, wherein the data verification display module comprises the following steps:

s31, the cloud platform queries according to the received first encryption result value ERV and the second encryption result value ERV 'to obtain a cloud platform storage first value corresponding to the first encryption result value ERV and a cloud platform storage second value corresponding to the second encryption result value ERV';

6. The big data government affairs analysis processing safety application platform according to claim 1, wherein the data verification display module comprises the following steps:

s31, the cloud platform queries according to the received first encryption result value ERV, the second encryption result value ERV 'and the third encryption result value ERV' to obtain a first value stored by the cloud platform corresponding to the first encryption result value ERV, a second value stored by the cloud platform corresponding to the second encryption result value ERV 'and a third value stored by the cloud platform corresponding to the third encryption result value ERV';

s32, calculating according to the first value stored by the cloud platform, the second value stored by the cloud platform and the third value stored by the cloud platform to obtain a first set of cloud platform combination values corresponding to the first value stored by the cloud platform, a second set of cloud platform combination values corresponding to the second value stored by the cloud platform and a third set of cloud platform combination values corresponding to the third value stored by the cloud platform;

if the first set of the cloud platform combined values, the second set of the cloud platform combined values and the third set of the cloud platform combined values have equal actual values, inquiring to obtain user information according to the actual values, and executing step S33;

7. The big data government affair analysis and processing safety application platform according to claim 1, wherein a data pre-storage module is included before the data acquisition module, and is used for storing the processed data in a database for query; the data pre-storing module comprises the following steps:

ORV″′＝MD(User Info″′)，

wherein, MD () represents a hashing algorithm using MD 5;

ORV' "represents the cloud platform operation result value;

ORV″′_a″′representing a numerical value corresponding to the a 'th bit in the ordering from low bit to high bit of the cloud platform operation result value ORV';

[A″′]^a″′-1is represented by [ A']A' "-1 to the power of;

S0222，

Wherein int () represents a rounding function;

[ B '"] indicates a scale value corresponding to the B'" scale;

a_i″′"' means iCircularly rounding the cloud platform amount;

a_i″′+1"'indicates the i' +1 cycle to round the cloud platform volume;

if a_i″′+1″′≥[B″′]I "" +1, return to step S0222;

s02221, enabling a circulating residual cloud platform parameter j' to be 1;

S02222，b_j″′″′＝a_j″′″′％[B″′]，

wherein,% represents the remainder;

[ B '"] indicates a scale value corresponding to the B'" scale;

a_j″′"'indicates the j' cycle rounding cloud platform quantity;

b_j″′"'indicates the j'" th cycle surplus cloud platform amount;

judging the relationship between j 'and i':

if j '≠ i' ″, j '″ is j' ″ +1, and the process returns to S22132;

if j 'is i', then B '} is B'_i″′″′b_i″′-1″′b_i″′-2″′…b₃″′b₂″′b₁″′；

Wherein { B '} represents a B' system cloud platform operation result;

b₂"' indicates the residual cloud platform quantity of the 2 nd cycle;

b₃"' indicates the residual cloud platform quantity of the 3 rd cycle;

b_i″′-2"'indicates the i' -2 loop residual cloud platform amount;

b_i″′-1"'indicates the i' -1 cycle residual cloud platform amount;

b_i″′"'indicates the i' cycle residual cloud platform amount;

s03, statistics are carried out on 0 to [ B '″) in the B' ″ system cloud platform operation result { B '″ }']The number of-1, written as | | (0, u)₀″′),(1,u₁″′),(2,u₂″′),(3,u₃″′),…,([B″′]-1,u_[B″′]-1″′)||_{B″′}，

Wherein (0, u)₀") indicates that the number of 0 s is u₀", said u₀"'is greater than or equal to 0 and less than or equal to < B' }>-1 is a positive integer; < B ' "} represents the total number of bits of the B '" binary cloud platform operation result { B ' "};

(1,u₁") indicates that the number of 1 s is u₁", said u₁"'is greater than or equal to 0 and less than or equal to < B' }>A positive integer of (d);

(2,u₂") indicates that the number of 2 is u₂", said u₂"'is greater than or equal to 0 and less than or equal to < B' }>A positive integer of (d);

(3,u₃") indicates that the number of 3 is u₃", said u₃"'is greater than or equal to 0 and less than or equal to < B' }>A positive integer of (d);

([B″′]-1,u_[B″′]-1") represents [ B"']The number of-1 is u_[B″′]-1", said u_[B″′]-1"'is a positive integer greater than or equal to 0 and less than or equal to < B'" >; u. of₀″′+u₁″′+u₂″′+u₃″′+...+u_[B″′]-1″′＝〈{B″′}〉；

S04, expressing the B' number cloud platform expression u₀″′u₁″′u₂″′u₃″′…u_[B″′]-1″′.[B″′]Carrying out the following operations to obtain an encryption result value of the cloud platform;

ERV″′＝MD(u₀″′u₁″′u₂″′u₃″′...u_[B″′]-1″′.[B″′])，

wherein, MD () represents a hashing algorithm using MD 5;

ERV' "represents a cloud platform encryption result value;

and S05, forming a cloud platform encryption result set by all the cloud platform encryption result values ERV 'of the cloud platform encryption result values ERV' and storing the cloud platform encryption result set and the cloud platform expression quantity corresponding to each element in the cloud platform encryption result set in a cloud platform database.