3D Landscape

Digital Surface Model

Digital Surface Model (DSM) represents the elevations of the reflective surfaces of trees, buildings, and other features elevated above the “Bare Earth”. It represents the earth’s surface and includes all objects on it.

We use algorithm-based high-end software that is patented to end-to-end photogrammetry solutions for the generation of high-quality geospatial data from satellite and aerial imagery, including UAVs. It builds on unique computer vision algorithms that significantly differ from traditional photogrammetry techniques. Powered by GPU technology and multi-core CPUs, it ensures matchless processing power to support the rapid production of large datasets.

Key Features of the product

• Automatic execution of the data with a defined workflow­
• GCP File Creation: a semi-automatic tool for creating and editing GCPs 
• Change Detection: identification of 3D changes ­ 
• Stitching of DSM patches ­ 
• DSM Inspection: generation of statistics about DSM quality ­ 
• Point Cloud Colorization: colorization of a point cloud using a mosaic ­ 
• Simple and user-friendly interface
• An unlimited number of images can be processed
• Survey-grade accuracy with detailed reports
• Fast processing on GPUs and multi-core CPUs
• Volume Calculation

Applications of a DSM

These models are used in planning, analysis, visualization, and modeling. 

1. Urban planning, architectural planning, tourism, virtual tours, etc.
2. For improving the transportation system
3. Telecommunication
4. Flood risk analysis and many others.
5. Runway Approach Zone Encroachment: DSMs in aviation can detect runway obstructions in the approach zone.
6. Vegetation Monitoring: DSMs can identify where and how much vegetation is intruding on a transmission line.
7. View Obstruction: DSM is being used by urban planners to evaluate how a proposed building will affect the viewsheds of businesses and residents.

Digital Terrain Model

Digital Terrain Model (DTM) is a bare earth model that is generated using stereo pair of imageries. Such models become an integral part of topographic surveys. These models are also used to generate contour maps. Such models are the best depiction of slopes and aspects.

Digital Terrain Models (DTM) sometimes called Digital Elevation Models (DEM) is a topographic models of the bare Earth that can be manipulated by computer programs. The data files contain the elevation data of the terrain in a digital format that relates to a rectangular grid. Vegetation, buildings, and other cultural features are removed digitally – leaving just the underlying terrain.

How the product is unique?

• Next-generation global 3D terrain datasets
• Seamless data up to sub-meter post spacing
• Precise topographic analysis
• Comprehensive worldwide offering
• Hydro-enforced – water bodies and coastlines are flattened for accurate measurement
• Vintage: most recent or new collected imagery
• File format: GeoTIFF or other formats on request
• Post Spacing: 50cm to 10m

Inputs Required

• Stereo remote sensing imagery
• Ground Control Points (GCPs).
• Contours
• Triangulate Irregular Network (TIN).

Workflow

Accuracy

• Absolute: 50cm to 5m (LE90)
• Valid on all-terrain type

Quality of the DTM

DTM is a measurement of how precise the elevation at each pixel is (absolute accuracy) and how precisely the morphology is presented (relative accuracy). So many factors have an impact on the quality of DTM:

• Terrain roughness
• Extracting terrain parameters
• Sampling density (elevation data collection method)
• Grid resolution or pixel size
• Interpolation algorithm
• Vertical resolution
• Terrain analysis algorithm
• Rendering of 3D visualizations

Add-on layers (feature extraction)

Application

• DTMs are used especially in civil engineering, geodesy & surveying, geophysics, geography, and remote sensing.
• Hydrology modeling
• Flood analysis
• Irrigation
• Feasibility study in infrastructure projects
• An essential part of a topographic survey
• Volume estimation in mining
• Input for orthorectification and many other

3D Buildings

New developments in urban planning, urban landscape, real estate management, and so on, call for new demands for the 3D Object Model. The building models are the most important in the 3D object model. With the development of 3D data acquisition, the visualization aspect often is detail considered.

Sometimes, there is no suitable 3D data or the auto-reconstruct process is not perfect to depict sufficient details, for instance, the balcony and a small tower in buildings can not be auto-reconstructed. The operator has to do this by himself. The 3D data can be used to create two basic categories of objects:

(1) point, line, and surface objects coinciding with a ground surface such as streets, roads, etc.

(2) volume objects that stick out the ground (buildings, towers, and so on ).

SATPALDA’s 3D building models can have these two categories. These models are derived photogrammetrically from high-resolution satellite and aerial imagery designed to support developers, architects, networks, and urban planners. It’s about giving shape, height, and elevation of the buildings based on the latest remote sensing imagery. 

Height:

• Mean Sea Level (MSL)
• Above Ground Level (AGL)

Accuracy:

• Absolute: 1m (LE90)

Delivery Formats:

• ESRI shapefile
• Mapinfo Tab
• Microstation DGN

Output:

Applications:

• These datasets are used for many simulations such as telecommunication, asset planning, analysis of the view
• Giving 3D tours in the real estate sector
• One can have a site layout
• Used in telecommunication projects
• Used in aviation where the height of buildings inside and near the airport is required
• Used in gaming and various simulators
• Used to measure the volume, and surface area of objects
• Incorporate new buildings into the existing urban model
• Edit the properties as per the modification
• Aesthetic assessment of an existing neighborhoods