CN114513582A

CN114513582A - Mineral resource data analysis method based on spatial big data technology

Info

Publication number: CN114513582A
Application number: CN202210069399.3A
Authority: CN
Inventors: 赵根; 陈坤; 朱丹; 汪蓓; 周宏文; 侯伟; 闫亮; 蒋正坤; 马小明; 黎欢; 刘青青; 周安强; 毛华锐; 曾令瑶; 靳莉君
Original assignee: Chongqing Planning And Natural Resources Information Center
Current assignee: Chongqing Planning And Natural Resources Information Center
Priority date: 2022-01-21
Filing date: 2022-01-21
Publication date: 2022-05-17
Anticipated expiration: 2042-01-21
Also published as: CN114513582B

Abstract

The invention provides a mineral resource data analysis method based on a spatial big data technology, which comprises mineral resource information acquisition equipment, an operation terminal and a cloud platform; the mineral resource information acquisition equipment is used for acquiring the identity information of a person delivering the mineral resource information; the operation terminal is used for merging the identity information acquired by the mineral resource information acquisition equipment and transmitting the merged information to the cloud platform; and the cloud platform is used for storing the uploaded merging information. The method can adopt the same background for the input identity images, is quick, convenient and efficient, and does not need to replace the background frequently.

Description

Mineral resource data analysis method based on spatial big data technology

Technical Field

The invention relates to the technical field of paperless, in particular to a mineral resource data analysis method based on a spatial big data technology.

Background

Paperless is an ideal target of an informatization process, the realization of the target is a process of gradual, continuous development and gradual recognition, and the paperless is a system engineering related to technical realization and social application. Patent application No. 2016103441556, the name is "a paperless system of getting a number of lining up", discloses that when customer received a number, the two-dimensional code was scanned with cell-phone APP, and the page jumped after the discernment was successful, shows the business option that this business outlet supported, and customer only need click the business of handling through the touch screen this moment can. And skipping to a queuing information page after the selection is finished, displaying the transacted service information, and updating the number of waiting people and the estimated time in real time. Can set for by customer according to the condition of oneself, when the certain time or every reduce a customer apart from the called number, the suggestion is sent out through popping out the prompt dialog box and vibration to client APP. If the customer has other things to process in the midway, the event processing software automatically clears the number from the service queue only by clicking a cancel button.

Disclosure of Invention

The invention aims to at least solve the technical problems in the prior art, and particularly provides a mineral resource data analysis method based on a spatial big data technology.

In order to achieve the aim, the invention provides a mineral resource data analysis system based on a spatial big data technology, which comprises mineral resource information acquisition equipment, an operation terminal and an end platform, wherein the operation terminal is used for acquiring mineral resource information;

the mineral resource information acquisition equipment is used for acquiring the identity information of a person delivering the mineral resource information;

the operation terminal is used for merging the identity information acquired by the mineral resource information acquisition equipment and transmitting the merged information to the cloud platform;

and the cloud platform is used for storing the uploaded merging information.

In a preferred embodiment of the present invention, the mineral resource information acquisition device includes a rectangular base, a touch display screen fixing installation area for fixedly installing a touch display screen, an identity card reader/writer fixing installation area for fixedly installing an identity card reader/writer, and a fingerprint identifier fixing installation area for fixedly installing a fingerprint identifier are provided on a surface of the base, the touch display screen is fixedly installed in the touch display screen fixing installation area, the identity card reader/writer is fixedly installed in the identity card reader/writer fixing installation area, and the fingerprint identifier is fixedly installed in the fingerprint identifier fixing installation area; the fingerprint recognizer and the identity card reader-writer are positioned on the left side or the right side of the touch display screen, and the fingerprint recognizer is positioned on the upper side or the lower side of the identity card reader-writer;

a circuit control board fixing mounting seat for fixedly mounting a circuit control board is arranged in the base, the circuit control board is fixedly mounted on the circuit control board fixing mounting seat, a controller and a data transmission module are arranged on the circuit control board, and a data transmission end of the data transmission module is connected with a data transmission end of the controller;

the touch display end of the touch display screen is connected with the touch display end of the controller, the data read-write end of the identity card reader-writer is connected with the data read-write end of the controller, and the fingerprint data end of the fingerprint recognizer is connected with the fingerprint data end of the controller;

still including setting up the detachable shooting device on the base, the shooting data end of shooting the device links to each other with the controller shooting data end, and still include the pronunciation broadcast module, the pronunciation data end of pronunciation broadcast module links to each other with the pronunciation data end of controller, the pronunciation broadcast module includes left voice module and right voice module, left voice module and right voice module are located touch display screen's upside, the shooting device is located the intermediate position of left voice module and right voice module.

In a preferred embodiment of the invention, the shooting device comprises a vertical upright rod, a transverse straight rod is arranged at the tail end of the vertical upright rod, a lower side face camera for shooting the front and the back of the identity card is arranged on the lower side face of the transverse straight rod, and the shooting data end of the lower side face camera is connected with the first end of the shooting data of the controller;

a recess which is matched with the other end of the vertical upright rod is arranged on the base, a rotating shaft is arranged in the recess, a supporting rod is arranged in the middle of the rotating shaft, a notch is arranged on the surrounding recess, an accommodating groove which is matched with the supporting rod is arranged at the bottom of the base, and when the rotating shaft rotates, the supporting rod rotates to the accommodating groove through the notch to be hidden;

the other end of the vertical upright rod is provided with a vertical supporting hole which is adaptive to the supporting rod and a transverse through recess which is adaptive to the rotating shaft; when the supporting rod extends into the vertical supporting hole, the rotating shaft is positioned in the transverse through recess;

or/and an upper side camera which can rotate and is used for shooting face images is arranged on the upper side of the transverse straight rod, and the shooting data end of the upper side camera is connected with the second end of the shooting data of the controller;

or/and the data transmission module comprises one or any combination of a USB2.0 data transmission module, a USB3.0 data transmission module, a USB3.1 data transmission module and a type-C data transmission module;

the data transmission end of the USB2.0 data transmission module is connected with the data transmission USB2.0 end of the controller, the data transmission end of the USB3.0 data transmission module is connected with the data transmission USB3.0 end of the controller, the data transmission end of the USB3.1 data transmission module is connected with the data transmission USB3.1 end of the controller, and the data transmission end of the type-C data transmission module is connected with the data transmission type-C end of the controller.

In a preferred embodiment of the present invention, an upright column is disposed on the upper side of the transverse straight rod, a first stepping motor is disposed in the upright column, the upper side camera is disposed on the rotation driving end of the first stepping motor, and the forward and reverse rotation control end of the first stepping motor is connected to the forward and reverse rotation control end of the first stepping motor of the controller;

a second stepping motor is arranged at the tail end of the vertical upright rod, the transverse straight rod is arranged on a rotation driving end of the second stepping motor, and a forward and reverse rotation control end of the second stepping motor is connected with a forward and reverse rotation control end of the second stepping motor of the controller;

be provided with non slipping spur and proximity sensor on identity card read write line fixed mounting region, the non slipping spur can be so that prevent the identity card certificate slip on identity card read write line fixed mounting region, and proximity sensor's the data output end that is close links to each other with the data input end that is close of controller, and when its certificate was placed on identity card read write line fixed mounting region, the controller received the proximity trigger signal that proximity sensor sent.

The invention also discloses a mineral resource data analysis method based on the spatial big data technology, which comprises the following steps:

s1, acquiring identity information;

s2, acquiring image information with the same background color, wherein the image information comprises identity card information;

s3, transmitting the image information obtained in the step S2 to an operation terminal;

s4, the operation terminal merges the received ID card information to obtain the merged information;

and S5, the operation terminal sends the image information to the cloud platform for storage.

In a preferred embodiment of the present invention, before the step S1, there is further provided a step S0 of assembling the photographing apparatus, the method of assembling the photographing apparatus including the steps of:

s01, the supporting rod is in an upright state after sequentially passing through the notch and the recess from the accommodating groove at the bottom of the base;

and S02, extending the support rod into the vertical support hole on the vertical upright rod, and enabling the rotating shaft to be in a transverse through recess, wherein the shooting device is in an upright state.

In a preferred embodiment of the present invention, step S1 includes the following steps:

and S11, judging whether a proximity trigger signal sent by the proximity sensor is received by the controller:

if the controller receives a proximity trigger signal sent by the proximity sensor, the controller sends a work control command to the identity card reader-writer;

if the controller does not receive the approach trigger signal sent by the approach sensor, the controller continues to wait and returns to the step S11;

s12, after the ID card reader-writer receives the ID card reader-writer work control command sent by the controller, the ID card reader-writer starts working to read the ID storage information in the ID card, wherein the ID storage information comprises one or any combination of name, ID card number, gender, family, birth year, month and day, address, issuing authority and expiry date;

s13, the ID card reader transmits the read ID storage information to the operation terminal;

s14, after receiving the identity storage information sent by the identity card reader, the operation terminal judges whether the current date is within the valid period:

if the Current date belongs to [ min Validity period, max Validity period ], wherein the Current date represents the Current date, the min Validity period represents the upper limit of the Validity period, the max Validity period represents the lower limit of the Validity period, [ min Validity period, max Validity period ] represents the set from the upper limit of the Validity period to the lower limit of the Validity period, and the e represents that the logic symbol belongs to, the identity certificate is a valid certificate; step S2 is executed;

if it is

Wherein the content of the first and second substances,

if the logic symbol does not belong to the ID card, the ID card is a failed card; executing the next step;

s15, the operation terminal sends a voice control signal to the controller, after the controller receives the voice control signal sent by the operation terminal, the controller controls the voice playing module to play voice, and the played voice is that the ID card is not in the valid period, please notice; and finishing the reading process.

In a preferred embodiment of the present invention, step S2 includes the following steps:

s20, the controller sends a forward rotation control command to the second stepping motor to enable the second stepping motor to rotate forward to drive the camera on the lower side face of the vertical upright rod to rotate to be opposite to the identity card shooting area on the touch display screen;

s21, the controller sends prompt information to the touch display screen, and the prompt information is displayed in the identity card shooting area of the touch display screen, and the prompt information is that the identity card is required to be placed on the front side;

s22, after the touch display screen receives the identity card certificate placed on the touch display screen, the controller sends a background color display control command to the touch display screen; after the touch display screen receives a control command of displaying background colors of the touch display screen sent by the controller, the touch display screen displays the background colors;

s23, the controller sends a lower side camera work control command to the lower side camera; after the lower side camera receives a lower side camera work control command sent by the controller, the lower side camera starts to work and collect the image data of the front side of the identity card document;

s24, after at least one piece of ID card document front image data collected by the lower camera, executing the next step;

s25, the controller sends prompt information to the touch display screen and sends voice prompt information to the voice playing module, and the voice prompt information is that the identity card is required to be turned over and placed on the reverse side; displaying prompt information in an identity card shooting area of the touch display screen, wherein the prompt information is that an identity card is required to be placed on the reverse side;

s26, after the touch display screen receives the ID card and the ID card is placed on the touch display screen again, the touch display screen displays the background color, and the camera on the lower side surface collects the image data of the reverse side of the ID card;

and S27, after at least one piece of identity card document reverse image data collected by the lower side camera is acquired, all identity card document front image data and identity card document reverse image data collected by the lower side camera are transmitted to the operation terminal.

In conclusion, due to the adoption of the technical scheme, the method and the device can adopt the same background for the input identity images, are quick, convenient and efficient, and do not need to replace the background frequently.

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 connection of the present invention.

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

FIG. 3 is a block diagram illustrating the flow 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 mineral resource data analysis system based on a spatial big data technology, which comprises mineral resource information acquisition equipment, an operation terminal and a cloud platform, wherein the mineral resource information acquisition equipment is shown in figure 1;

the operation terminal is used for merging the identity information acquired by the mineral resource information acquisition equipment and transmitting the merged information to the cloud platform; the operation terminal and the cloud platform are transmitted to the cloud platform through one of WiFi, hundred-megabyte wired network card broadband and kilomega wired network card broadband.

And the cloud platform is used for storing the uploaded merging information.

In a preferred embodiment of the present invention, as shown in fig. 2, the mineral resource information collecting device includes a rectangular base 6, a touch display screen fixing installation area 5 for fixedly installing a touch display screen 4, an identification card reader-writer fixing installation area for fixedly installing an identification card reader-writer 9, and a fingerprint recognizer fixing installation area 7 for fixedly installing a fingerprint recognizer 8 are provided on the surface of the base 6, the touch display screen 4 is fixedly installed in the touch display screen fixing installation area 5, the identification card reader-writer 9 is fixedly installed in the identification card reader-writer fixing installation area, and the fingerprint recognizer 8 is fixedly installed in the fingerprint recognizer fixing installation area 7; the fingerprint recognizer 8 and the identity card reader-writer 9 are positioned on the left side or the right side of the touch display screen 4, and the fingerprint recognizer 8 is positioned on the upper side or the lower side of the identity card reader-writer 9;

a circuit control board fixing mounting seat for fixedly mounting a circuit control board is arranged in the base 6, the circuit control board is fixedly mounted on the circuit control board fixing mounting seat, a controller and a data transmission module are arranged on the circuit control board, and a data transmission end of the data transmission module is connected with a data transmission end of the controller;

the touch display end of the touch display screen 4 is connected with the touch display end of the controller, the data read-write end of the identity card reader-writer 9 is connected with the data read-write end of the controller, and the fingerprint data end of the fingerprint recognizer 8 is connected with the fingerprint data end of the controller;

still including setting up the detachable shooting device on base 6, the shooting data end of shooting the device is continuous with the controller shooting data end, and still include pronunciation broadcast module 2, the pronunciation data end of pronunciation broadcast module 2 links to each other with the pronunciation data end of controller, pronunciation broadcast module 2 includes left voice module and right voice module, left voice module and right voice module are located the upside of touch display screen 4, the shooting device is located the intermediate position of left voice module and right voice module.

In a preferred embodiment of the invention, the shooting device comprises a vertical upright rod 1, a transverse straight rod 11 is arranged at the tail end of the vertical upright rod 1, a lower side face camera 12 for shooting the front and the back of the identity card is arranged on the lower side face of the transverse straight rod 11, and the shooting data end of the lower side face camera 12 is connected with the first end of the shooting data of the controller;

a recess which is matched with the other end of the vertical upright rod 1 is arranged on the base 6, a rotating shaft is arranged in the recess, a supporting rod is arranged in the middle of the rotating shaft, a notch is arranged on the recess, an accommodating groove which is matched with the supporting rod is arranged at the bottom of the base 6, and when the rotating shaft rotates, the supporting rod rotates to the accommodating groove through the notch to be hidden;

the other end of the vertical upright rod 1 is provided with a vertical supporting hole which is adaptive to the supporting rod and a transverse through recess which is adaptive to the rotating shaft; when the supporting rod extends into the vertical supporting hole, the rotating shaft is positioned in the transverse through recess;

or/and an upper side camera 10 which can rotate and is used for shooting face images is arranged on the upper side of the transverse straight rod 11, and the shooting data end of the upper side camera 10 is connected with the second end of the shooting data of the controller;

In a preferred embodiment of the present invention, an upright is disposed on the upper side of the transverse straight rod 11, a first stepping motor is disposed in the upright, the upper side camera 10 is disposed on the rotation driving end of the first stepping motor, and the forward and reverse rotation control end of the first stepping motor is connected to the forward and reverse rotation control end of the first stepping motor of the controller;

a second stepping motor is arranged in the tail end of the vertical upright rod 1, the transverse straight rod 11 is arranged on a rotation driving end of the second stepping motor, and a forward and reverse rotation control end of the second stepping motor is connected with a forward and reverse rotation control end of the second stepping motor of the controller;

The invention also discloses a mineral resource data analysis method based on the spatial big data technology, which comprises the following steps as shown in figure 3:

s1, acquiring identity information;

In a preferred embodiment of the present invention, before step S1, further comprising step S0, the method of assembling the camera comprises the steps of:

s01, the supporting rod is in an upright state after sequentially passing through the notch and the recess from the accommodating groove at the bottom of the base 6;

and S02, extending the support rod into the vertical support hole on the vertical upright rod 1, and enabling the rotating shaft to be in a transverse through recess, wherein the shooting device is in an upright state.

if the controller receives a proximity trigger signal sent by the proximity sensor, the controller sends a work control command to the identity card reader-writer 9;

s12, after the ID card reader 9 receives the ID card reader work control command sent by the controller, the ID card reader 9 starts working to read the ID storage information in the ID card, wherein the ID storage information comprises one or any combination of name, ID card number, gender, family of names, birth year, month and day, address, issuing authority and valid period;

s13, the ID card reader 9 transmits the read ID storage information to the operation terminal;

s14, after receiving the identity storage information sent by the identity card reader 9, the operation terminal determines whether the current date is within the validity period:

if it is

Wherein the content of the first and second substances,

s15, the operation terminal sends a voice control signal to the controller, after the controller receives the voice control signal sent by the operation terminal, the controller controls the voice playing module 2 to play voice, and the played voice is that the ID card is not in the valid period, please notice; and finishing the reading process.

s20, when the shooting surface of the lower side camera 12 is opposite to the identity card shooting area 3, the controller sends a forward (reverse) rotation control command to the second stepping motor, so that the second stepping motor positively rotates (reversely rotates) to drive the lower side camera 12 on the vertical upright rod 1 to rotate to be opposite to the identity card shooting area 3 on the touch display screen 4;

s21, the controller sends prompt information to the touch display screen 4, and the prompt information is displayed in the identity card shooting area 3 of the touch display screen 4, wherein the prompt information is that the identity card is required to be placed on the front side;

s22, after the touch display screen 4 receives the identity card certificate placed on the touch display screen 4, the controller sends a background color display control command displayed by the touch display screen 4 to the touch display screen 4; after the touch display screen 4 receives a control command of displaying the background color of the touch display screen 4 sent by the controller, the touch display screen 4 displays the background color;

s23, the controller sends a lower-side camera operation control command to the lower-side camera 12; after the lower side camera 12 receives a lower side camera work control command sent by the controller, the lower side camera 12 starts to work to collect the image data of the front side of the identity card document;

s24, after at least one piece of ID card document front image data collected by the lower camera 12, executing the next step;

s25, the controller sends prompt information to the touch display screen 4 and sends voice prompt information to the voice playing module 2, wherein the voice prompt information is that the identity card is turned over and placed on the reverse side; displaying prompt information in an identity card shooting area 3 of a touch display screen 4, wherein the prompt information is that an identity card is required to be placed on the reverse side;

s26, after the touch display screen 4 receives the ID card document and puts the ID card document on the touch display screen 4 again, the touch display screen 4 firstly displays the background color, and the camera 12 at the lower side surface collects the image data of the reverse side of the ID card document;

and S27, after at least one piece of identity card document back image data collected by the lower side camera 12, transmitting all identity card document front image data and identity card document back image data collected by the lower side camera 12 to an operation terminal. The lower side face camera 12 on the transverse straight rod 11 of the second stepping motor is just opposite to the identity card document, and the general second stepping motor drives the vertical upright rod 1 to rotate clockwise (positive rotation) or anticlockwise (negative rotation) for half a circle, namely a pi angle. When the identity card document does not need to be shot, the transverse straight rod 11 is far away from the touch display screen 4, and the obstruction caused when the identity card document is signed or read on the touch display screen 4 is avoided. When shooting, the whole touch display screen 4 displays a background color, wherein the background color at least comprises one or any combination of red, orange, yellow, green, cyan, blue and purple, and also can comprise pink, gray, white and black, and is used as a background color (background color) of the identity card, and the identity card is used as a target color (foreground color); the certificate does not need to be shot, and the background cloth is laid additionally, so that the color and the pattern of the background cloth can be adjusted according to the actual situation.

In a preferred embodiment of the present invention, the method further comprises acquiring fingerprint information, and the acquiring fingerprint information comprises the following steps:

s2-1, the controller sends a fingerprint recognizer work control command to the fingerprint recognizer 8;

s2-2, after the fingerprint recognizer 8 receives a fingerprint recognizer work control command sent by the controller, the fingerprint recognizer 8 starts to work to collect fingerprint image data;

s2-3, after at least one piece of fingerprint image data collected by the fingerprint recognizer 8, the controller transmits all the fingerprint image data collected by the fingerprint recognizer 8 to the operation terminal;

the method also comprises the step of obtaining the face information, wherein the step of obtaining the face information comprises the following steps:

s2-a, when the face of the user is on the back of the upper side camera 10, the controller sends a forward (reverse) rotation control command to the first stepping motor, so that the first stepping motor rotates forward (reverse) to drive the upper side camera 10 to rotate to be opposite to the face to be shot;

s2-b, the controller sends an upper side camera work control command to the upper side camera 10;

s2-c, after the upper side camera 10 receives the upper side camera work control command sent by the controller, the upper side camera 10 starts to work to collect face image data;

s2-d, after at least one piece of face image data collected by the upper side camera 10, the controller transmits all the face image data collected by the upper side camera 10 to the operation terminal; the upper side camera 10 is rotated to face the human face by the first stepping motor, and the general first stepping motor drives the upper side camera 10 to rotate clockwise (forward rotation) or anticlockwise (reverse rotation) for half a cycle, namely, a pi angle.

In a preferred embodiment of the present invention, step S4 includes the following steps:

s41, collecting { I ] from the front face images of the identity card document_{N, 1},I_{N.2 is},I_{N, 3},…,I_{N, P}Selecting an image with the highest definition as a positive image I_{N, p}And from the set of reverse side images { I } of the identification card document_{Trans, 1},I_{Trans, 2},I_{Trans, 3},…,I_{Trans, Q}Selecting an image with the highest definition as a reverse image I_{Trans, q}(ii) a Wherein, I_{N, 1}Denotes the 1 st positive image, I_{N.2 is}Denotes the 2 nd positive image, I_{N, 3}Denotes the 3 rd positive image, I_{N, P}Denotes the P isThe image P represents the total number of the images of the front side of the identity card document collected by the camera 12 at the lower side surface; i is_{Trans, 1}Denotes the 1 st inverse image, I_{Trans, 2}Representing the 2 nd inverse image, I_{Trans, 3}Denotes the 3 rd inverse image, I_{Trans, Q}The Q & ltth & gt reverse image is shown, and Q is the total number of the images of the reverse side of the identity card and the certificate collected by the camera 12 at the lower side surface;

s42, acquiring a positive image I_{N, p}Or/and inverse image I_{Trans, q}Width value, height value and resolution:

if K ≧ G, where K denotes the positive image I_{N, p}Or/and inverse image I_{Trans, q}G represents a positive image I_{N, p}Or/and inverse image I_{Trans, q}If the height value is less than the preset height value, establishing a canvas with the size of 2 Kx 2K, and executing the next step by setting W to be 2K;

if K is less than G, establishing a canvas with the size of 2G multiplied by 2G, and executing the next step by making W equal to 2G;

s43, taking the left lower endpoint of the canvas as the origin of coordinates, the right lower edge of the canvas as the positive direction of the X axis and the upward left edge of the canvas as the positive direction of the Y axis, and obtaining the coordinate point set of the pixel points of the canvas

(x_k,y_g) The coordinates of the pixel points at the X-axis k and Y-axis g points are represented, where k is 0,1, 2, … …, W '-1, and g is 0,1, 2, … …, W' -1, (X)₀,y₀) Representing the coordinates of the pixel points at X-axis 0 point and Y-axis 0 point, (X)₀,y₁) Representing the coordinates of the pixel points at X-axis 0 point and Y-axis 1 point, (X)₀,y₂) Representing the coordinates of the pixel points at X-axis 0 point and Y-axis 2 point, (X)₀,y_W′-1) Representing the coordinates of pixel points at the X-axis 0 point and the Y-axis W' -1 point; (x)₁,y₀) Representing the coordinates of the pixel points at X-axis 1 point and Y-axis 0 point, (X)₁,y₁) Representing the coordinates of the pixel points at X-axis 1 point and Y-axis 1 point, (X)₁,y₂) Representing the coordinates of the pixel points at X-axis 1 point and Y-axis 2 point, (X)₁,y_W′-1) Indicating pixel locations at X-axis 1 point and Y-axis W' -1 pointMarking; (x)₂,y₀) Representing the coordinates of the pixel points at X-axis 2 point and Y-axis 0 point, (X)₂,y₁) Representing the coordinates of the pixel points at X-axis 2 point and Y-axis 1 point, (X)₂,y₂) Representing the coordinates of the pixel points at X-axis 2 point and Y-axis 2 point, (X)₂,y_W′-1) The coordinates of pixel points at the X-axis 2 point and the Y-axis W' -1 point are represented; (x)_W′-1,y₀) Representing the coordinates of the pixel points at the X-axis W' -1 point and the Y-axis 0 point, (X)_W′-1,y₁) Representing the coordinates of the pixel points at the X-axis W' -1 point and the Y-axis 1 point, (X)_W′-1,y₂) Representing the coordinates of the pixel points at the X-axis W' -1 point and the Y-axis 2 point, (X)_W′-1,y_W′-1) The coordinates of the pixel points at the X-axis W '-1 point and the Y-axis W' -1 point are represented; w 'is W × Image Resolution, W' represents the total number of pixels drawn on the X axis and the Y axis, Image Resolution represents Image Resolution, and W represents intermediate replacement amount;

s44, with positive image I_{N, p}Is the origin of coordinates, positive image I_{N, p}Is in the positive X-axis direction to the right, positive image I_{N, p}The left edge of the image is upward in the positive direction of the Y axis to obtain a positive image I of the image_{N, p}Set of pixel point coordinates

(x_k′,y_g′) 'denotes positive pixel point coordinates at an X-axis K' point and a Y-axis G 'point, K' -0, 1, 2, … …, K '-1, G' -0, 1, 2, … …, G '-1, (X' -1)₀,y₀) ' denotes the coordinates of the positive pixel points at the X-axis 0 point and the Y-axis 0 point, (X)₀,y₁) ' denotes the coordinates of a positive pixel point at the X-axis 0 point and the Y-axis 1 point, (X)₀,y₂) ' denotes the coordinates of the positive pixel points at the X-axis 0 point and the Y-axis 2 point, (X)₀,y_G′-1) 'represents the positive pixel point coordinates at the X-axis 0 point and the Y-axis G' -1 point; (x)₁,y₀) ' denotes the positive pixel point coordinates at the X-axis 1 point and the Y-axis 0 point, (X)₁,y₁) ' denotes the positive pixel point coordinates at the X-axis 1 point and the Y-axis 1 point, (X)₁,y₂) ' indicates at X-axis 1 point and Y-axis 2 pointPositive pixel point coordinates, (x)₁,y_G′-1) 'represents the positive pixel point coordinates at the X-axis 1 point and the Y-axis G' -1 point; (x)₂,y₀) ' denotes the positive pixel point coordinates at the X-axis 2 point and the Y-axis 0 point, (X)₂,y₁) ' denotes the positive pixel point coordinates at X-axis 2 point and Y-axis 1 point, (X)₂,y₂) ' denotes the positive pixel point coordinates at the X-axis 2 point and the Y-axis 2 point, (X)₂,y_G′-1) 'represents the positive pixel point coordinates at the X-axis 2 point and the Y-axis G' -1 point; (x)_K′-1,y₀) 'denotes the coordinates of a positive pixel point at the X-axis K' -1 point and the Y-axis 0 point, (X)_K′-1,y₁) 'denotes the coordinates of the positive pixel points at the X-axis K' -1 point and the Y-axis 1 point, (X)_K′-1,y₂) 'denotes the coordinates of a positive pixel point at the X-axis K' -1 point and the Y-axis 2 point, (X)_K′-1,y_G′-1) ' represents the positive pixel point coordinates at the X-axis K ' -1 point and the Y-axis G ' -1 point; k 'is K × Image Resolution, K' represents the total number of X-axis pixels, G 'is G × Image Resolution, and G' represents the total number of Y-axis pixels;

with inverse image I_{Trans, q}The lower left end point of (1) is the origin of coordinates, inverse image I_{Trans, q}Is in the positive X-axis direction to the right, and is in the negative image I_{Trans, q}The left edge of the image is upward and is the positive direction of the Y axis, and a reverse image I of the image is obtained_{Trans, q}Set of pixel point coordinates

(x_k″,y_g″) "denotes the inverse pixel point coordinates at the X-axis K" point and the Y-axis G "point, K ″ -0, 1, 2, … …, K ' -1, G ″ -0, 1, 2, … …, G ' -1, (X ″ -0, 1, 2, … …, G ' -1₀,y₀) "denotes the coordinates of the inverse pixel points at the X-axis 0 point and the Y-axis 0 point, (X)₀,y₁) "denotes the coordinates of the inverse pixel points at the X-axis 0 point and the Y-axis 1 point, (X)₀,y₂) "denotes the coordinates of the inverse pixel points at the X-axis 0 point and the Y-axis 2 point, (X)₀,y_G′-1) "represents the inverse pixel point coordinates at the X-axis 0 point and the Y-axis G' -1 point; (x)₁,y₀) "indicates at 1 point on the X-axis and the Y-axisInverse pixel point coordinates at point 0, (x)₁,y₁) "denotes the coordinates of the inverse pixel points at the X-axis 1 point and the Y-axis 1 point, (X)₁,y₂) "denotes the coordinates of the inverse pixel points at the X-axis 1 point and the Y-axis 2 point, (X)₁,y_G′-1) "denotes the inverse pixel point coordinates at the X-axis 1 point and the Y-axis G' -1 point; (x)₂,y₀) "denotes the coordinates of the inverse pixel points at the X-axis 2 point and the Y-axis 0 point, (X)₂,y₁) "denotes the coordinates of the inverse pixel points at the X-axis 2 point and the Y-axis 1 point, (X)₂,y₂) "denotes the coordinates of the inverse pixel points at the X-axis 2 point and the Y-axis 2 point, (X)₂,y_G′-1) "denotes the inverse pixel point coordinates at the X-axis 2 point and the Y-axis G' -1 point; (x)_K′-1,y₀) "denotes the coordinates of the inverse pixel points at the X-axis K' -1 point and the Y-axis 0 point, (X)_K′-1,y₁) "denotes the coordinates of the inverse pixel points at the X-axis K' -1 point and the Y-axis 1 point, (X)_K′-1,y₂) "denotes the coordinates of the inverse pixel points at the X-axis K' -1 point and the Y-axis 2 point, (X)_K′-1,y_G′-1) "denotes the inverse pixel point coordinates at the X-axis K '-1 point and the Y-axis G' -1 point;

s45, inverse pixel point coordinates

The corresponding color intensity is arranged in the coordinate of the canvas pixel point

1. 2, … …, K '-1, τ 0,1, 2, … …, G' -1, positive pixel point coordinates

τ '═ τ + G'; that is, the inverse pixel point coordinates (x)₀,y₀) "the corresponding color saturation is placed in the coordinate (x) of canvas pixel point₀,y₀) Inverse pixel point coordinates (x)₀,y₁) What is rightThe corresponding color intensity is arranged in the coordinate (x) of the canvas pixel point₀,y₁) Inverse pixel point coordinates (x)₀,y₂) The corresponding color intensity is arranged at the coordinate (x) of the canvas pixel point₀,y₂) … …, inverse pixel point coordinates (x)₀,y_G′-1) The corresponding color intensity is arranged at the coordinate (x) of the canvas pixel point₀,y_G′-1) (ii) a Will invert the pixel point coordinates (x)₁,y₀) The corresponding color intensity is arranged at the coordinate (x) of the canvas pixel point₁,y₀) Inverse pixel point coordinates (x)₁,y₁) The corresponding color intensity is arranged at the coordinate (x) of the canvas pixel point₁,y₁) Inverse pixel point coordinates (x)₁,y₂) The corresponding color intensity is arranged at the coordinate (x) of the canvas pixel point₁,y₂) … …, inverse pixel point coordinates (x)₁,y_G′-1) The corresponding color intensity is arranged at the coordinate (x) of the canvas pixel point₁,y_G′-1) (ii) a Will invert the pixel point coordinates (x)₂,y₀) The corresponding color intensity is arranged at the coordinate (x) of the canvas pixel point₂,y₀) Inverse pixel point coordinates (x)₂,y₁) The corresponding color intensity is arranged at the coordinate (x) of the canvas pixel point₂,y₁) Inverse pixel point coordinates (x)₂,y₂) The corresponding color intensity is arranged at the coordinate (x) of the canvas pixel point₂,y₂) … …, inverse pixel point coordinates (x)₂,y_G′-1) The corresponding color intensity is arranged at the coordinate (x) of the canvas pixel point₂,y_G′-1) (ii) a … …; will invert the pixel point coordinates (x)_K′-1,y₀) The corresponding color intensity is arranged at the coordinate (x) of the canvas pixel point_K′-1,y₀) Inverse pixel point coordinates (x)_K′-1,y₁) The corresponding color intensity is arranged at the coordinate (x) of the canvas pixel point_K′-1,y₁) Inverse pixel point coordinates (x)_K′-1,y₂) The corresponding color intensity is arranged at the coordinate (x) of the canvas pixel point_K′-1,y₂) … …, inverse pixel point coordinates (x)_K′-1,y_G′-1) The corresponding color intensity is arranged at the coordinate (x) of the canvas pixel point_K′-1,y_G′-1)；

Will have positive pixel point coordinates (x)₀,y₀) ' the corresponding color intensity is arranged in the coordinate (x) of the canvas pixel point_K′,y_G′) The positive pixel point coordinate (x)₀,y₁) ' the corresponding color intensity is arranged in the coordinate (x) of the canvas pixel point_K′,y_G′+1) The positive pixel point coordinate (x)₀,y₂) ' the corresponding color intensity is arranged in the coordinate (x) of the canvas pixel point_K′,y_G′+2) … …, positive pixel point coordinates (x)₀,y_G′-1) ' the corresponding color intensity is arranged in the coordinate (x) of the canvas pixel point_K′,y_2G′-1) (ii) a Will have a positive pixel point coordinate (x)₁,y₀) ' the corresponding color intensity is arranged in the coordinate (x) of the canvas pixel point_K′+1,y_G′) The positive pixel point coordinate (x)₁,y₁) ' the corresponding color intensity is arranged in the coordinate (x) of the canvas pixel point_K′+1,y_G′+1) The positive pixel point coordinate (x)₁,y₂) ' the corresponding color intensity is arranged in the coordinate (x) of the canvas pixel point_K′+1,y_G′+2) … …, positive pixel point coordinates (x)₁,y_G′-1) ' the corresponding color intensity is arranged in the coordinate (x) of the canvas pixel point_K′+1,y_2G′-1) (ii) a Will have a positive pixel point coordinate (x)₂,y₀) ' the corresponding color intensity is arranged in the coordinate (x) of the canvas pixel point_K′+2,y_G′) The positive pixel point coordinate (x)₂,y₁) ' the corresponding color intensity is arranged in the coordinate (x) of the canvas pixel point_K′+2,y_G′+1) The positive pixel point coordinate (x)₂,y₂) ' the corresponding color intensity is arranged in the coordinate (x) of the canvas pixel point_K′+2,y_G′+2) … …, positive pixel point coordinates (x)₂,y_G′-1) ' the corresponding color intensity is arranged in the coordinate (x) of the canvas pixel point_K′+2,y_2G′-1) (ii) a … …, respectively; will have a positive pixel point coordinate (x)_K′-1,y₀) ' the corresponding color intensity is arranged in the coordinate (x) of the canvas pixel point_2K′-1,y_G′) The positive pixel point coordinate (x)_K′-1,y₁) ' the corresponding color intensity is arranged in the canvas pixelPoint coordinates (x)_2K′-1,y_G′+1) The positive pixel point coordinate (x)_K′-1,y₂) ' the corresponding color intensity is arranged in the coordinate (x) of the canvas pixel point_2K′-1,y_G′+2) … …, positive pixel point coordinates (x)_K′-1,y_G′-1) ' the corresponding color intensity is arranged in the coordinate (x) of the canvas pixel point_2K′-1,y_2G′-1) (ii) a The merged information is obtained, and the merged information is also the front and back images of the identity card image.

In a preferred embodiment of the invention, the set of I images from the front side of the identification card document is collected in step S41_{N, 1},I_{N, 2},I_{N, 3},…,I_{N, P}Selecting an image with the highest definition as a positive image I_{Positive, p}The method comprises the following steps:

s411, let p' be 1;

s412, judging the p' th positive image I_{N, p'}Whether it is a p' th gray scale positive image:

if the p' th positive image I_{N, p'}If the image is a positive p' gray level image, executing the next step;

if the p' th positive image I_{N, p'}If not, the p' th positive gray image I is selected_{N, p'}Converting into p 'th gray positive image, and converting into p' th positive image I_{N, p'}The method for converting the image into the p' th gray positive image comprises the following steps:

wherein the content of the first and second substances,

represents the p' th positive image I_{N, p'}The gray value at the pixel point coordinate (x, y), that is, the gray value of the p' th gray positive image at the pixel point coordinate (x, y);

represents the p' th positive image I_{N, p'}A red color value at pixel point coordinate (x, y);

denotes the p' th positive image I_{N, p'}A green color value at pixel point coordinate (x, y);

represents the p' th positive image I_{N, p'}A blue color value at pixel point coordinate (x, y);

r represents the adjustment parameter of the red color value, and r belongs to [0,1 ];

g represents an adjusting parameter of a green color value, and g belongs to [0,1 ];

b represents an adjustment parameter for the blue color value, b ∈ [0,1], and r + g + b ═ 1;

s413, calculating a fused pixel value of the p 'th gray level positive image, wherein the method for calculating the fused pixel value of the p' th gray level positive image comprises:

wherein the content of the first and second substances,

representing the fusion pixel value of the p' th gray level positive image at the pixel point coordinate (x, y);

representing the horizontal pixel value of the p' th gray positive image at the pixel point coordinate (x, y);

expressing the longitudinal pixel value of the p' th gray positive image at the pixel point coordinate (x, y);

wherein the content of the first and second substances,

expressing the gray value of the p' th gray positive image at the pixel point coordinate (x +1, y-1);

expressing the gray value of the p' th gray positive image at the pixel point coordinate (x +1, y);

expressing the gray value of the p' th gray positive image at the pixel point coordinate (x +1, y + 1);

expressing the gray value of the p' th gray positive image at the pixel point coordinate (x-1, y-1);

expressing the gray value of the p' th gray positive image at the pixel point coordinate (x-1, y);

expressing the gray value of the p' th gray positive image at the pixel point coordinate (x-1, y + 1);

wherein the content of the first and second substances,

expressing the gray value of the p' th gray positive image at the pixel point coordinate (x, y-1);

expressing the gray value of the p' th gray positive image at the pixel point coordinate (x, y + 1);

s414, calculating a standard deviation of the fused pixel value of the p 'th gray level positive image, wherein the standard deviation calculating method of the fused pixel value of the p' th gray level positive image comprises:

wherein the content of the first and second substances,

a standard deviation of a fused pixel value representing a p' th gray-scale positive image;

k' represents the total number of X-axis pixel points;

g' represents the total number of Y-axis pixel points;

means representing a fused pixel value of a p' th gray positive image;

s415, judging the relation between P' and P:

if P' is not less than P, executing the next step;

if P > P ', P' +1, return to step S412;

and S416, arranging the standard deviations from small to large in sequence, and taking the image corresponding to the first standard deviation as the image with the highest definition.

In a preferred embodiment of the invention, the set of reverse side images { I } from the identification card document in step S41_{Trans, 1},I_{Trans, 2},I_{Trans, 3},…,I_{Trans, Q}Selecting an image with the highest definition as a reverse image I_{Trans, q}The method comprises the following steps:

s41a, changing q' to 1;

s41b, judging the q' th inverse image I_{N, p'}Whether it is a q' th gray scale reverse image:

if the q' th inverse image I_{Trans, q}If the image is the q' th gray scale reverse image, the next step is executed;

if the q' th inverse image I_{Trans, q}If not, the q' th inverse image I is processed_{Trans, q}Converting into q 'th grey inverse image, and converting into q' th inverse image I_{Trans, q}The method for converting the image into the q' th gray scale reverse image comprises the following steps:

wherein, the first and the second end of the pipe are connected with each other,

representing the q' th inverse image I_{Trans, q}The gray value at the pixel point coordinate (x, y), that is, the gray value of the q' th gray inverse image at the pixel point coordinate (x, y);

representing the q' th inverse image I_{Trans, q}A red color value at pixel point coordinate (x, y);

representing the q' th inverse image I_{Trans, q}A green color value at pixel point coordinate (x, y);

representing the q' th inverse image I_{Trans, q}A blue color value at pixel point coordinate (x, y);

s41c, calculating a fused pixel value of the q 'th gray-scale reverse image, wherein the method for calculating the fused pixel value of the q' th gray-scale reverse image comprises:

wherein the content of the first and second substances,

representing the fusion pixel value of the q' th gray-scale inverse image at the pixel point coordinate (x, y);

representing the horizontal pixel value of the q' th gray-scale reverse image at the pixel point coordinate (x, y);

represents the vertical of the q' th gray-scale inverse image at the pixel point coordinate (x, y)To the pixel value;

wherein the content of the first and second substances,

expressing the gray value of the q' th gray inverse image at the pixel point coordinate (x +1, y-1);

expressing the gray value of the q' th gray inverse image at the pixel point coordinate (x +1, y);

expressing the gray value of the q' th gray inverse image at the pixel point coordinate (x +1, y + 1);

expressing the gray value of the q' th gray inverse image at the pixel point coordinate (x-1, y-1);

expressing the gray value of the q' th gray inverse image at the pixel point coordinate (x-1, y);

expressing the gray value of the q' th gray inverse image at the pixel point coordinate (x-1, y + 1);

wherein the content of the first and second substances,

expressing the gray value of the q' th gray inverse image at the pixel point coordinate (x, y-1);

expressing the gray value of the q' th gray inverse image at the pixel point coordinate (x, y + 1);

s41d, calculating a standard deviation of the fused pixel value of the q 'th gray-scale reverse image, wherein the standard deviation of the fused pixel value of the q' th gray-scale reverse image is calculated by:

wherein the content of the first and second substances,

a standard deviation of a fused pixel value representing a q' th gray-scale reverse image;

k' represents the total number of X-axis pixel points;

g' represents the total number of Y-axis pixel points;

a mean value of the fused pixel values representing the q' th gray-scale inverse image;

s41e, judging the relation between Q' and Q:

if Q' is not less than Q, executing the next step;

if Q > Q ', Q ' ═ Q ' +1, return to step S41 b;

and S41f, arranging the standard deviations from big to small in sequence, and taking the image corresponding to the last standard deviation as the image with the highest definition.

In a preferred embodiment of the present invention, in step S5, the sending, by the operation terminal, the image information to the cloud platform for storage includes the following steps:

s51, compressing image data to be sent to a cloud-end platform by the operation terminal in the existing modes of rar, zip and the like, wherein the image data comprises a fingerprint image, a face image and an identity card image (merging information), and obtaining a compressed data packet to be transmitted;

s52, executing transmission security algorithm to the compressed data packet to be transmitted obtained in the step S51 to obtain a security transmission code, wherein the calculation method of the security transmission code is as follows:

Secure Transmission Number＝Transmission Security Function[Compressed Data Packet]，

wherein, the Secure Transmission Number represents a Secure Transmission code;

the Compressed Data Packet represents a Compressed Data Packet to be transmitted;

transmission Security Function [ ] represents the Transmission Security algorithm, and the Hash MD5 algorithm is adopted;

s53, the secure transmission code obtained in the step S52 is used as the file name of the compressed data package to be transmitted, and the renamed data package to be transmitted is obtained; transmitting the renamed data packet to be transmitted to a cloud platform;

s54, the cloud platform executes a transmission security algorithm on the received transmission data packet to obtain a proofreading transmission code, and the calculation method of the proofreading transmission code is as follows:

Proofread Transmission Number＝Transmission Security Function[Transmission Data Packet]，

wherein, the Proofread Transmission Number represents the proofreading Transmission code;

transmission Data Packet represents the Data Packet to be transmitted;

s55, determining whether the proofreading Transmission Number calculated in step S54 matches the file name corresponding to the Transmission data packet received by the cloud platform in step S54:

if the proofreading Transmission Number calculated in step S54 is consistent with the file name corresponding to the Transmission data packet received by the cloud platform in step S54, decompressing the received Transmission data packet by the cloud platform, and storing the decompressed file.

If the proof reading Transmission Number calculated in step S54 is not consistent with the file name corresponding to the Transmission data packet received by the cloud platform in step S54, the cloud platform requests the operation terminal to resend the data packet corresponding to the file name corresponding to the Transmission data packet received by the cloud platform.

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 mineral resource data analysis system based on a spatial big data technology is characterized by comprising mineral resource information acquisition equipment, an operation terminal and an end platform;

and the cloud platform is used for storing the uploaded merging information.

2. The mineral resource data analysis system based on the spatial big data technology according to claim 1, characterized in that the mineral resource information collection device comprises a rectangular base (6), a touch display screen fixing and mounting area (5) for fixedly mounting the touch display screen (4), an identity card reader fixing and mounting area for fixedly mounting the identity card reader (9), and a fingerprint recognizer fixing and mounting area (7) for fixedly mounting the fingerprint recognizer (8) are provided on the surface of the base (6), the touch display screen (4) is fixedly mounted on the touch display screen fixing and mounting area (5), the identity card reader (9) is fixedly mounted on the identity card reader fixing and mounting area, and the fingerprint recognizer (8) is fixedly mounted on the fingerprint recognizer fixing and mounting area (7); the fingerprint recognizer (8) and the identity card reader-writer (9) are positioned on the left side or the right side of the touch display screen (4), and the fingerprint recognizer (8) is positioned on the upper side or the lower side of the identity card reader-writer (9);

a circuit control board fixing mounting seat for fixedly mounting a circuit control board is arranged in the base (6), the circuit control board is fixedly mounted on the circuit control board fixing mounting seat, a controller and a data transmission module are arranged on the circuit control board, and a data transmission end of the data transmission module is connected with a data transmission end of the controller;

the touch display end of the touch display screen (4) is connected with the touch display end of the controller, the data read-write end of the identity card reader-writer (9) is connected with the data read-write end of the controller, and the fingerprint data end of the fingerprint recognizer (8) is connected with the fingerprint data end of the controller;

still including setting up detachable shooting device on base (6), the shooting data end of shooting device links to each other with the controller shooting data end, and still include pronunciation broadcast module (2), the pronunciation data end of pronunciation broadcast module (2) links to each other with the pronunciation data end of controller, pronunciation broadcast module (2) are including left voice module and right voice module, left side voice module and right voice module are located the upside of touch display screen (4), the shooting device is located the intermediate position of left voice module and right voice module.

3. The mineral resource data analysis system based on the spatial big data technology as claimed in claim 2, characterized in that the photographing device comprises a vertical upright (1), a transverse straight rod (11) is arranged at the end of the vertical upright (1), a lower side camera (12) for photographing the front and back of the identity card is arranged on the lower side of the transverse straight rod (11), and the photographing data end of the lower side camera (12) is connected with the first end of the photographing data of the controller;

a recess which is matched with the other end of the vertical upright rod (1) is arranged on the base (6), a rotating shaft is arranged in the recess, a supporting rod is arranged in the middle of the rotating shaft, a notch is arranged on the recess, an accommodating groove which is matched with the supporting rod is arranged at the bottom of the base (6), and when the rotating shaft rotates, the supporting rod rotates to the accommodating groove through the notch to be hidden;

the other end of the vertical upright rod (1) is provided with a vertical supporting hole adaptive to the supporting rod and a transverse penetrating dent adaptive to the rotating shaft; when the supporting rod extends into the vertical supporting hole, the rotating shaft is positioned in the transverse through recess;

or/and an upper side camera (10) which can rotate and is used for shooting face images is arranged on the upper side surface of the transverse straight rod (11), and the shooting data end of the upper side camera (10) is connected with the second end of the shooting data of the controller.

4. The mineral resource data analysis system based on the space big data technology as claimed in claim 3, characterized in that a vertical column is arranged on the upper side of the transverse straight rod (11), a first stepping motor is arranged in the vertical column, the upper side camera (10) is arranged on the rotation driving end of the first stepping motor, and the forward and reverse rotation control end of the first stepping motor is connected with the forward and reverse rotation control end of the first stepping motor of the controller;

a second stepping motor is arranged in the tail end of the vertical upright rod (1), the transverse straight rod (11) is arranged on the rotation driving end of the second stepping motor, and the forward and reverse rotation control end of the second stepping motor is connected with the forward and reverse rotation control end of the second stepping motor of the controller;

5. A mineral resource data analysis method based on a spatial big data technology is characterized by comprising the following steps:

s1, acquiring identity information;

s2, obtaining image information with the same background color, wherein the image information comprises identity card information;

6. The method for analyzing mineral resource data based on spatial big data technology according to claim 5, characterized in that step S1 includes the following steps:

if the controller receives a proximity trigger signal sent by the proximity sensor, the controller sends a work control command to the identity card reader-writer (9) of the controller;

s12, after the ID card reader-writer (9) receives the ID card reader-writer work control command sent by the controller, the ID card reader-writer (9) starts to work to read the ID storage information in the ID card, wherein the ID storage information comprises one or any combination of name, ID card number, gender, family, birth year, month and day, address, issuing authority and validity period;

s13, the ID card reader (9) transmits the read ID storage information to the operation terminal;

s14, after receiving the identity storage information sent by the identity card reader-writer (9), the operation terminal judges whether the current date is within the valid period:

if it is

s15, the operation terminal sends a voice control signal to the controller, after the controller receives the voice control signal sent by the operation terminal, the controller controls the voice playing module (2) to play voice, and the played voice is that the ID card is not in the valid period, please notice; and finishing the reading process.

7. The method for analyzing mineral resource data based on the spatial big data technology according to claim 5, characterized in that in step S2, the method includes the following steps:

s20, the controller sends a forward rotation control command to the second stepping motor to enable the second stepping motor to rotate forward to drive the lower side face camera (12) on the vertical upright rod (1) to rotate to be opposite to the identity card shooting area (3) on the touch display screen (4);

s21, the controller sends prompt information to the touch display screen (4), and the prompt information is displayed in the identity card shooting area (3) of the touch display screen (4), wherein the prompt information is that the identity card is required to be placed on the front side;

s22, after the touch display screen (4) receives the identity card certificate placed on the touch display screen (4), the controller sends a background color display control command displayed by the touch display screen (4) to the touch display screen (4); after the touch display screen (4) receives a control command of displaying the background color of the touch display screen (4) sent by the controller, the touch display screen (4) displays the background color;

s23, the controller sends a lower side camera work control command to the lower side camera (12); after the lower side camera (12) receives a lower side camera work control command sent by the controller, the lower side camera (12) starts to work to collect image data of the front side of the identity card document;

s24, after at least one piece of ID card certificate front image data collected by the lower side camera (12), executing the next step;

s25, the controller sends prompt information to the touch display screen (4) and sends voice prompt information to the voice playing module (2), and the voice prompt information is that the identity card is turned over and placed on the reverse side; displaying prompt information in an identity card shooting area (3) of the touch display screen (4), wherein the prompt information is that an identity card is required to be placed on the reverse side;

s26, after the touch display screen (4) receives the ID card document and puts the ID card document on the touch display screen (4) again, the touch display screen (4) displays the background color, and the camera (12) on the lower side collects the image data of the reverse side of the ID card document;

s27, after at least one piece of ID card document reverse image data collected by the lower side camera (12), all ID card document front image data and ID card document reverse image data collected by the lower side camera (12) are transmitted to the operation terminal.