CN114863845A - Yellow river holographic simulation dynamic display system - Google Patents
Yellow river holographic simulation dynamic display system Download PDFInfo
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- CN114863845A CN114863845A CN202210601888.9A CN202210601888A CN114863845A CN 114863845 A CN114863845 A CN 114863845A CN 202210601888 A CN202210601888 A CN 202210601888A CN 114863845 A CN114863845 A CN 114863845A
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- 238000004088 simulation Methods 0.000 title claims abstract description 59
- 238000009877 rendering Methods 0.000 claims abstract description 54
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- 238000012544 monitoring process Methods 0.000 claims abstract description 14
- 238000000034 method Methods 0.000 claims abstract description 9
- 238000004891 communication Methods 0.000 claims description 13
- 238000012545 processing Methods 0.000 claims description 13
- 238000010276 construction Methods 0.000 claims description 8
- 238000013479 data entry Methods 0.000 claims description 7
- 230000002159 abnormal effect Effects 0.000 claims description 5
- 230000011218 segmentation Effects 0.000 claims description 4
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- G—PHYSICS
- G09—EDUCATION; CRYPTOGRAPHY; DISPLAY; ADVERTISING; SEALS
- G09F—DISPLAYING; ADVERTISING; SIGNS; LABELS OR NAME-PLATES; SEALS
- G09F19/00—Advertising or display means not otherwise provided for
- G09F19/12—Advertising or display means not otherwise provided for using special optical effects
- G09F19/125—Stereoscopic displays; 3D displays
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- G—PHYSICS
- G03—PHOTOGRAPHY; CINEMATOGRAPHY; ANALOGOUS TECHNIQUES USING WAVES OTHER THAN OPTICAL WAVES; ELECTROGRAPHY; HOLOGRAPHY
- G03B—APPARATUS OR ARRANGEMENTS FOR TAKING PHOTOGRAPHS OR FOR PROJECTING OR VIEWING THEM; APPARATUS OR ARRANGEMENTS EMPLOYING ANALOGOUS TECHNIQUES USING WAVES OTHER THAN OPTICAL WAVES; ACCESSORIES THEREFOR
- G03B35/00—Stereoscopic photography
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- G—PHYSICS
- G06—COMPUTING; CALCULATING OR COUNTING
- G06T—IMAGE DATA PROCESSING OR GENERATION, IN GENERAL
- G06T15/00—3D [Three Dimensional] image rendering
- G06T15/005—General purpose rendering architectures
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- G06V—IMAGE OR VIDEO RECOGNITION OR UNDERSTANDING
- G06V40/00—Recognition of biometric, human-related or animal-related patterns in image or video data
- G06V40/20—Movements or behaviour, e.g. gesture recognition
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Abstract
The invention discloses a yellow river holographic simulation dynamic display system, which relates to the field of holographic simulation, and adopts the technical scheme that the system comprises a holographic simulation host, wherein the holographic simulation host internally comprises an image system, a data system, a demonstration adjusting system and a human-computer interaction module, collects external images and data, builds a yellow river holographic simulation display scene according to the collected data, carries out real-time interaction according to the limb actions of participants in the built scene, and stores the data in the holographic simulation host in real time through a cloud storage module; the human-computer interaction module comprises a monitoring camera, the image system comprises an image acquisition module, an image recognition module, an image splicing module and an action capturing module, the adjustment of rendering scheduling in the interaction process is realized through the cooperation of the real-time rendering module and the rendering adjusting module, the smooth running of the whole system is ensured, and the experience feeling of participants is increased.
Description
Technical Field
The invention relates to the technical field of holographic simulation, in particular to a yellow river holographic simulation dynamic display system.
Background
With the continuous development of display technology, the holographic display technology has the advantages that the holographic display technology can meet the full perception of human vision, and an observer can observe without the help of auxiliary devices such as helmets, glasses and the like, and more attention is paid.
The view can be put on the body and classic through holographic simulation, and a feeling of being personally on the scene is provided for people.
However, the conventional holographic simulation system can only perform holographic simulation display on input parameters in the using process, but does not capture and analyze the work of people in the actual using process, so that the interactivity of the holographic simulation display is reduced, the interaction is performed in real time, the load of the system is greatly increased, the regulation and control on real-time rendering are lacked, the use experience of users is reduced, and therefore the yellow river holographic simulation dynamic display system is needed.
Disclosure of Invention
The invention aims to solve the defects that the prior art lacks of capturing and analyzing the work of a character, so that the interactivity of holographic simulation display is reduced, real-time interaction is carried out, the load of a system is greatly increased, and simultaneously, the control of real-time rendering is lacked, and the use experience of users is reduced.
In order to achieve the purpose, the invention adopts the following technical scheme:
a yellow river holographic simulation dynamic display system comprises a holographic simulation host, wherein the holographic simulation host comprises an image system, a data system, a demonstration adjusting system and a human-computer interaction module, the holographic simulation host collects external images and data, meanwhile, a yellow river holographic simulation display scene is built according to the collected data, real-time interaction is carried out according to the limb actions of participants in the built scene, and the data in the holographic simulation host is stored in real time through a cloud storage module;
the interior of the human-computer interaction module comprises a monitoring camera, the interior of the image system comprises an image acquisition module, an image identification module, an image splicing module and a motion capture module, and the image system acquires, identifies and splices images shot by the monitoring camera and converts motion forms of participants into limb data information;
the data system comprises a data entry module and a data processing module, the data system enters the data of the yellow river and processes the entered data, the data system is in communication connection with the demonstration adjusting system, and the data system transmits the data to the demonstration adjusting system;
the demonstration adjusting system comprises a parameter configuration module, a holographic scene building module, a real-time rendering module and a rendering adjusting module, the demonstration adjusting system adjusts parameters according to received data, builds a yellow river holographic simulation demonstration scene according to the adjusted parameters, and meanwhile performs real-time rendering according to the limb data information of participants.
The above technical solution further comprises:
the monitoring camera shoots the actions of the participators in real time, the image acquisition module acquires images shot in the monitoring camera in real time, the image acquisition module is in communication connection with the image identification module, the image acquisition module transmits the acquired images to the image identification module, and the image identification module identifies the received images.
The content identified by the image identification module comprises the limb state of a participant, the image identification module is in communication connection with the image splicing module, the image identification module transmits the identified content to the image splicing module, and the image splicing module is spliced with other body state characteristics of the participant according to the limb state identified by the image identification module.
The image splicing module is in communication connection with the motion capture module, the image splicing module transmits spliced image content to the motion capture module, the motion capture module performs node segmentation on the limb state of a participant in the image, and then performs recognition analysis on the segmented node motion condition, so that the captured language is converted into corresponding data.
The data of the yellow river is recorded through the data recording module, the data recording module transmits the data to the data processing module, and the data processing module analyzes the recorded data and removes abnormal data in the data.
The parameter configuration module is used for inputting data in the data system, meanwhile, the parameter configuration module is used for carrying out parameter configuration according to the data in the data system, the parameter configuration module is used for transmitting configuration parameters to the holographic scene building module, and the holographic scene building module is used for building a yellow river holographic simulation display scene according to the parameters in the parameter configuration module.
The motion capture data transmitted to the demonstration adjusting system are subjected to parameter configuration through the parameter configuration module, the parameter configuration module transmits configuration parameters to the holographic scene building module, the built yellow river holographic simulation demonstration scene is changed through the holographic scene building module, and the real-time rendering module performs real-time rendering according to the parameters transmitted by the parameter configuration module, so that real-time interaction is achieved.
The rendering adjusting module adjusts according to the load of real-time rendering in the real-time rendering module, and the rendering adjusting module relieves the high load of rendering in the real-time rendering module by a method of reducing the rendering quality.
Compared with the prior art, the invention has the beneficial effects that:
1. according to the method, the data system and the demonstration adjusting system are matched to use to realize the input of external parameters, the yellow river holographic simulation display scene is established according to the input parameters, and the data processing module in the data system can automatically eliminate abnormal data in the input data, so that the accuracy of the yellow river holographic simulation display scene is ensured.
2. According to the invention, the action postures of the participants can be captured in real time through the cooperative use of the image system and the demonstration adjusting system, and meanwhile, the captured action postures are transmitted to the parameter configuration module in an information data form for parameter configuration, so that the yellow river holographic simulation display scene is changed in real time, the model can be interacted with the participants in real time, the adjustment of rendering scheduling in the interaction process is realized through the cooperative use of the real-time rendering module and the rendering adjusting module, the smooth running of the whole system is ensured, and the experience feeling of the participants is increased.
Drawings
FIG. 1 is a block diagram of a yellow river holographic simulation dynamic display system according to the present invention;
FIG. 2 is a system block diagram of an imaging system according to the present invention;
FIG. 3 is a system block diagram of a data system of the present invention.
In the figure: 1. a holographic simulation host; 2. an image system; 3. a data system; 4. a demonstration adjustment system; 5. a human-computer interaction module; 6. a parameter configuration module; 7. a holographic scene building module; 8. a cloud storage module; 9. a real-time rendering module; 10. a rendering adjustment module; 11. a surveillance camera; 12. an image acquisition module; 13. an image recognition module; 14. an image stitching module; 15. a motion capture module; 16. a data entry module; 17. and a data processing module.
Detailed Description
The technical solution of the present invention is further explained with reference to the accompanying drawings and specific embodiments.
Example one
As shown in fig. 1-3, the yellow river holographic simulation dynamic display system provided by the invention comprises a holographic simulation host 1, wherein the holographic simulation host 1 internally comprises an image system 2, a data system 3, a demonstration adjusting system 4 and a man-machine interaction module 5, the holographic simulation host 1 collects external images and data, meanwhile, a holographic simulation scene is built according to the collected data, real-time interaction is carried out according to the limb actions of participants in the built scene, and the data in the holographic simulation host 1 is stored in real time through a cloud storage module 8;
the inside of the human-computer interaction module 5 comprises a monitoring camera 11, the inside of the image system 2 comprises an image acquisition module 12, an image recognition module 13, an image splicing module 14 and a motion capture module 15, the image system 2 acquires, recognizes and splices images shot by the monitoring camera 11, and the motion forms of participators are converted into limb data information;
the data system 3 comprises a data entry module 16 and a data processing module 17, the data system 3 enters the data of the yellow river and processes the entered data, the data system 3 is in communication connection with the demonstration adjusting system 4, and the data system 3 transmits the data to the demonstration adjusting system 4;
the demonstration adjusting system 4 comprises a parameter configuration module 6, a holographic scene building module 7, a real-time rendering module 9 and a rendering adjusting module 10, the demonstration adjusting system 4 adjusts parameters according to received data, builds a yellow river holographic simulation demonstration scene according to the adjusted parameters, and performs real-time rendering according to the limb data information of participants;
the data of the yellow river is recorded through the data recording module 16, the data recording module 16 transmits the data to the data processing module 17, and the data processing module 17 analyzes the recorded data and removes abnormal data in the data;
the parameter configuration module 6 records data in the data system 3, the parameter configuration module 6 performs parameter configuration according to the data in the data system 3, the parameter configuration module 6 transmits configuration parameters to the holographic scene construction module 7, and the holographic scene construction module 7 constructs a yellow river holographic simulation display scene according to the parameters in the parameter configuration module 6.
The yellow river holographic simulation dynamic display system based on the first embodiment has the working principle that when the yellow river holographic simulation dynamic display system works, data are imported into the data entry module 16 through a U disk or the Internet, the data imported by the data entry module 16 are entered, the data entry module 16 transmits the data to the data processing module 17, and the data processing module 17 analyzes the entered data and removes abnormal data existing in the data;
the data system 3 transmits the processed data to the parameter configuration module 6, the parameter configuration module 6 records the data in the data system 3, the parameter configuration module 6 performs parameter configuration according to the recorded data, the parameter configuration module 6 transmits configuration parameters to the holographic scene building module 7, and the holographic scene building module 7 builds a yellow river holographic simulation display scene according to the parameters in the parameter configuration module 6.
Example two
As shown in fig. 1 to 3, based on the first embodiment, the monitoring camera 11 shoots the actions of the participants in real time, the image acquisition module 12 acquires the images shot by the monitoring camera 11 in real time, the image acquisition module 12 is in communication connection with the image recognition module 13, the image acquisition module 12 transmits the acquired images to the image recognition module 13, and the image recognition module 13 recognizes the received images;
the content identified by the image identification module 13 comprises the limb state of a participant, the image identification module 13 is in communication connection with the image splicing module 14, the image identification module 13 transmits the identified content to the image splicing module 14, and the image splicing module 14 splices the limb state identified by the image identification module 13 with other body state characteristics of the participant;
the image splicing module 14 is in communication connection with the motion capture module 15, the image splicing module 14 transmits spliced image content to the motion capture module 15, the motion capture module 15 performs node segmentation on the limb state of the participators in the image, and then performs recognition analysis on the segmented node motion situation, so that the captured language is converted into corresponding data.
In the embodiment, during work, the actions of the participants are photographed in real time through the holographic simulation host 1, the image acquisition module 12 acquires images photographed in the monitoring camera 11 in real time, the image acquisition module 12 transmits the acquired images to the image recognition module 13, the image recognition module 13 recognizes the received images, and the contents recognized by the image recognition module 13 include the limb states of the participants;
the image recognition module 13 transmits the recognized content to the image stitching module 14, the image stitching module 14 stitches the limb state recognized by the image recognition module 13 with other body state characteristics of the participant, the image stitching module 14 transmits the stitched image content to the motion capture module 15, the motion capture module 15 performs node segmentation on the limb state of the participant in the image, and then performs recognition analysis on the segmented node motion situation, so as to convert the captured language into corresponding motion data.
EXAMPLE III
As shown in fig. 1-3, based on the first or second embodiment, the motion capture data transmitted to the demonstration adjusting system 4 is subjected to parameter configuration by the parameter configuration module 6, the parameter configuration module 6 transmits the configuration parameters to the real-time rendering module 9, and the real-time rendering module 9 performs real-time rendering according to the parameters, so as to achieve real-time interaction;
the rendering adjustment module 10 adjusts according to the load of the real-time rendering in the real-time rendering module 9, and the rendering adjustment module 10 relieves the high load of the rendering in the real-time rendering module 9 by reducing the rendering quality.
In this embodiment, during operation, the motion capture module 15 and the parameter configuration module 6 are in communication connection, the motion capture module 15 transmits motion data to the parameter configuration module 6 for parameter configuration, the parameter configuration module 6 transmits configuration parameters to the holographic scene construction module 7, the holographic scene construction module 7 changes the established holographic simulation display scene of the yellow river, the real-time rendering module 9 performs real-time rendering according to the parameters transmitted by the parameter configuration module 6, so as to achieve real-time interaction, the rendering adjustment module 10 performs adjustment according to a load rendered in the real-time rendering module 9, the rendering adjustment module 10 relieves a high load rendered in the real-time rendering module 9 by reducing rendering quality, thereby ensuring smooth operation of the entire system, and increasing experience of participants.
The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be considered as the technical solutions and the inventive concepts of the present invention within the technical scope of the present invention.
Claims (8)
1. A yellow river holographic simulation dynamic display system comprises a holographic simulation host (1), and is characterized in that the holographic simulation host (1) internally comprises an image system (2), a data system (3), a demonstration adjusting system (4) and a human-computer interaction module (5), the holographic simulation host (1) collects external images and data, meanwhile, a yellow river holographic simulation display scene is built according to the collected data, real-time interaction is carried out according to the limb actions of participants in the built scene, and the data in the holographic simulation host (1) is stored in real time through a cloud storage module (8);
the human-computer interaction module (5) comprises a monitoring camera (11), the image system (2) comprises an image acquisition module (12), an image recognition module (13), an image splicing module (14) and a motion capture module (15), and the image system (2) acquires, recognizes and splices images shot by the monitoring camera (11) and converts motion forms of participants into limb data information;
the data system (3) comprises a data entry module (16) and a data processing module (17), the data system (3) enters the data of the yellow river and processes the entered data, the data system (3) is in communication connection with the demonstration adjusting system (4), and the data system (3) transmits the data to the demonstration adjusting system (4);
the demonstration adjusting system (4) comprises a parameter configuration module (6), a holographic scene building module (7), a real-time rendering module (9) and a rendering adjusting module (10) inside, the demonstration adjusting system (4) adjusts parameters according to received data, a yellow river holographic simulation demonstration scene is built according to the adjusted parameters, and meanwhile real-time rendering is carried out according to limb data information of participants.
2. The yellow river holographic simulation dynamic display system according to claim 1, wherein the monitoring camera (11) shoots the motion of the participators in real time, the image acquisition module (12) acquires the images shot in the monitoring camera (11) in real time, the image acquisition module (12) is in communication connection with the image recognition module (13), the image acquisition module (12) transmits the acquired images to the image recognition module (13), and the image recognition module (13) recognizes the received images.
3. The yellow river holographic simulation dynamic display system according to claim 2, wherein the content identified by the image identification module (13) comprises the limb state of a participant, the image identification module (13) is in communication connection with the image stitching module (14), the image identification module (13) transmits the identified content to the image stitching module (14), and the image stitching module (14) stitches other body state features of the participant according to the limb state identified by the image identification module (13).
4. The yellow river holographic simulation dynamic display system according to claim 3, wherein the image splicing module (14) is in communication connection with the motion capture module (15), the image splicing module (14) transmits spliced image contents to the motion capture module (15), the motion capture module (15) performs node segmentation on the limb states of the participants in the image, and then performs recognition analysis on the segmented node motion conditions, so as to convert captured language into corresponding data.
5. The yellow river holographic simulation dynamic display system according to claim 4, wherein data of the yellow river is recorded through the data recording module (16), the data recording module (16) transmits the data to the data processing module (17), and the data processing module (17) analyzes the recorded data to remove abnormal data existing in the data.
6. The yellow river holographic simulation dynamic display system according to claim 5, wherein the parameter configuration module (6) records data in the data system (3), the parameter configuration module (6) performs parameter configuration according to the data in the data system (3), the parameter configuration module (6) transmits configuration parameters to the holographic scene construction module (7), and the holographic scene construction module (7) constructs a yellow river holographic simulation display scene according to the parameters in the parameter configuration module (6).
7. The yellow river holographic simulation dynamic display system according to claim 6, wherein the motion capture data transmitted to the demonstration adjustment system (4) is subjected to parameter configuration through the parameter configuration module (6), the parameter configuration module (6) transmits configuration parameters to the holographic scene construction module (7), the holographic scene construction module (7) changes the created yellow river holographic simulation display scene, and the real-time rendering module (9) performs real-time rendering according to the parameters transmitted by the parameter configuration module (6) to achieve real-time interaction.
8. The yellow river holographic simulation dynamic display system according to claim 7, wherein the rendering adjustment module (10) adjusts according to the load of real-time rendering in the real-time rendering module (9), and the rendering adjustment module (10) relieves the high load of rendering in the real-time rendering module (9) by reducing the rendering quality.
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