Cloud tourism, cloud viewing exhibitions, immersive performances, immersive amusement has become a trend in contemporary entertainment.

The scenic spot fully combines artificial intelligence, virtual reality and other technologies to digitize cultural and tourism resources, so that tourists can have an immersive and interactive experience before and during the trip. Comprehensive information, history of actual attendance, load at the clean hands, pressure on nearby parking lots, pressure on public transportation near the gates, crowd density, analysis of complaint causes, handling of today's events, evacuation simulation, and so on.

Modernized scenic spots will bring more immersive and interactive experiences to tourists after absorbing the results of the information revolution (5G/6G), the Internet revolution (Web 3.0), the artificial intelligence revolution, and the virtual reality technology revolution within VR, AR, and MR.

Entry statistics

Separately count the number of people who booked tickets on the Internet, purchased tickets on the spot, and left the park, and connect the data of intelligent monitoring equipment and face recognition to the visualization system to realize active security. Operation and maintenance can always pay attention to the visitor data in the visualization system, control the number of visitors in the park in a reasonable range, and satisfy the operation and maintenance personnel to carry out real-time situational awareness of the scene, historical data retrospective comparison, and emergency treatment.

Restroom guidance

Built within the intelligent scenic 3D scene, you can know the public **** restroom flow interface, displaying the number of people in line. It also provides statistics on the number of people using men's toilets, women's toilets, and accessible public toilets; the load of public toilets in each area; the history of environmental scoring; environmental data such as nitrogen, temperature, humidity, and PM2.5; and realizes the digital management of the scenic area. Hightopo's visualization technology supports the integration of various types of video resources to form a unified video stream, which can be used to mark the camera objects on the 2D and 3D situational maps and correlate the sources of their video signals, and to call the corresponding video sources through scenario interaction. The video streams can be accessed through scene interactions.

Actual attendance history

Realizes year-over-year, year-over-year, and real-time data display of average daily attendance. The graphical means to clearly and effectively interpret and convey the data information, help us discover the patterns and characteristics, and explore the value behind the data.

Load at Net Hand

The progress bar displays the percentage of load factor at Net Hand, and O&M can use the large visualization screen to view the location of crowded areas, and pass the location information to security personnel through wearable devices such as smart bracelets.

Public transportation pressure near each gate: Statistics on public transportation near scenic spots to facilitate visitors' travel.

Today's event processing: The statistics of the events that have been processed, to be dispatched, have been looking for, and to be sent out to the police can assess the performance of the management personnel in the scenic area and optimize the management of personnel.

Complaint Cause Analysis

Dynamic charts show the number of tour guide services, tour guide violations, traffic problems, facility problems, and tour group violations. The use of rich charts, graphs and design elements will be relatively complex, abstract data through the visual way to a more intuitive understanding of the form of display, to facilitate the management of scenic spots.

Heat map

The crowd density in the scenic area is getting higher and higher, and group incidents are increasing day by day, the dense flow of people increases the difficulties in security, service and other management. Through the image recognition and analysis of multiple intelligent cameras, a complete heat map of the park can be formed. It shows the concentration of people in a certain place in the park and the degree of congestion, with crowds gathering in red areas and fewer visitors in green areas.

Crowd density analysis uses advanced target detection, identification, tracking and other technologies to count the number of crowds and density and other characteristic indicators to monitor the safety of crowds in public *** places, helping us to grasp the correct crowd density data and change trends, so as to carry out reasonable security management. Visualization monitoring form help to carry out passenger flow monitoring can establish passenger flow early warning mechanism, to exceed the carrying capacity of the scenic area of the passenger flow for effective guidance and evacuation, in advance to consider the crowd evacuation routes.

Dynamic arrows point to the direction of the escape exit, can simulate multiple evacuation routes and predict the time, measured the best escape route. The scenic area is characterized by high density of people and complex terrain, etc. The real evacuation environment and evacuation situation are restored, and the real situation in the scenic area is highly relevant. Therefore, in the actual disaster escape, it will be able to effectively improve the efficiency of tourists escape.

Digital twin of the Forbidden City palace layout ancient style scenes, with magpies and flying cranes set off the classical style, combined with sci-fi color scheme, with red bricks and yellow tiles of the Forbidden City, the long history of China to tell the story. Access to VR equipment for the tour can achieve an immersive effect and bring an immersive experience.

About the Scenic Area GIS

It can show more details of the ground objects in the 3D scenic area. The 3D scene data can be acquired through aerial modeling or manual modeling. Aerial photography modeling that tilt photography real three-dimensional. The use of aircraft or drones carrying multiple sensors, from the front, back, left, right and vertical five directions on the ground features to capture data information. Through the correction, leveling, multi-view image matching and other processing operations to obtain three-dimensional model. Manual modeling is mainly based on a certain range of scene maps or CAD drawings combined with real-life photos for manual modeling.

The result data of aerial modeling has geographic coordinate system information, which can be accurately matched with GIS, and manual modeling needs to be manually corrected and aligned in order to match with GIS. The .osgb model data of aerial modeling has multiple levels of detail (LOD), and the system can display LOD level models with different accuracy according to the distance between the user's browsing and the scene, which improves the efficiency of data display and rendering.

Aerial modeling is not as fine as manual modeling. If you need to query, analyze, and edit simple models, you need to monolithically process aerial photography, but restoration requires a longer cycle and higher costs, so monolithic processing is applied to key buildings or monuments.