Metashape leverages your graphics card (GPU) for the most demanding tasks like image alignment and dense cloud generation, significantly cutting down processing time.
The jump to version 2 (and subsequent updates like 2.1, 2.2, and 2.3) brought several "field-ready" enhancements: LiDAR & Laser Scan Integration
The standard processing pipeline follows a logical sequence: photo alignment (sparse cloud), dense cloud generation, mesh construction, and texturing. Recent updates in version 2.2 have further refined these workflows for aerial projects.
For those in mapping and surveying, the quality of the orthomosaic is non-negotiable.
Use Python scripting to automate repetitive processing tasks and customize your workflow. 4. Hardware Optimization
Version 2.0 fundamentally rewrites the logic behind orthomosaic generation. In legacy workflows, orthomosaics were often plagued by seam lines—visible borders where images with different exposure values or capture angles were stitched together.
Metashape leverages your graphics card (GPU) for the most demanding tasks like image alignment and dense cloud generation, significantly cutting down processing time.
The jump to version 2 (and subsequent updates like 2.1, 2.2, and 2.3) brought several "field-ready" enhancements: LiDAR & Laser Scan Integration
The standard processing pipeline follows a logical sequence: photo alignment (sparse cloud), dense cloud generation, mesh construction, and texturing. Recent updates in version 2.2 have further refined these workflows for aerial projects.
For those in mapping and surveying, the quality of the orthomosaic is non-negotiable.
Use Python scripting to automate repetitive processing tasks and customize your workflow. 4. Hardware Optimization
Version 2.0 fundamentally rewrites the logic behind orthomosaic generation. In legacy workflows, orthomosaics were often plagued by seam lines—visible borders where images with different exposure values or capture angles were stitched together.