Many of South Africa’s assets have outdated or missing records. Whether privately-owned or part of State infrastructure, missing records are unfortunately a common problem. Without accessible data, professional teams are hamstrung at the outset of projects, having to make assumptions on the layout, composition, and condition of facilities.
Surveying buildings is a time-consuming activity, often not budgeted for in the early stages of a project’s start-up. All too often the professional teams rely on educated guesswork and one or two site visits with photographs to formulate their initial project proposals.
“When we execute engineering projects, we rely on comprehensive base data. Projects that involve existing structures and facilities require accurate records of existing conditions. Without proper data, our designs cannot be founded on fact,” stresses Zutari Digital Practice Lead Richard Matchett.
The Company has met the challenge head on by investing significant time and resources to investigate various technological approaches to capture the reality at its sites in digitised form, using virtual environments to assess and understand those spaces in a scientific, integrated manner.
This has resulted in its recent acquisition of the Leica BLK2GO handheld imaging laser scanner, believed to be one of only two available in South Africa at present. The scanner is an example of an innovative technology known as Simultaneous Localisation and Mapping (SLAM).
SLAM is based on an algorithm that combines laser technology with photogrammetry and data from movement sensors. The handheld laser device contains the scanner, cameras, and movement sensors in a single package. When the scanner is carried through an environment, it records 450 000 measurements per second in all directions to incrementally accumulate a 3D picture.
In contrast, Zutari has been using drones for over two years to capture site conditions, adds Reality Capture Leader Louis De Klerk (Jnr). The point clouds and ortho-imagery derived in this manner are used in its design and spatial analysis packages to provide context for the design teams, reducing reliance on repeated site visits by bringing the outside world into the office space.
However, whilst the company’s mature 3D laser-scanning offering has proven invaluable in mapping indoor spaces to sub-millimetre tolerances, giving its designers and professional partners confidence that the designs are relevant to the actual physical spaces on-site, there have been notable gaps.
These include spaces where layouts are needed quickly, or complex layouts where the interaction between adjacent and interconnected spaces must be understood in a timeframe too brief to undertake conventional 3D scanning.
Another issue is speeding up the process of familiarising designers with a remote site, in addition to rapidly capturing the maximum quantity of data, both geometrically and visually, in an integrated manner so that it can be accessed effectively by engineering design applications.
“We tested a variety of these scanners and were most impressed by the functionality of the SLAM system to enable rapid collection of data, which we used to extract floorplans, volumetric spaces and locate plant and equipment in buildings, all as part of our hands-on testing of the available options,” explains Matchett.
The main requirements were to be able to spend the shortest time on-site to capture a comprehensive overview to enable anyone else to visit the site virtually within a day or two. The system also had to provide a robust processing interface to combine multiple scans of large facilities. After extensive testing, the Leica BLK2GO scanner was acquired.
The Leica BLK2GO’s so-called ‘GrandSLAM’ technology combines LiDAR SLAM, Visual SLAM and an IMU to deliver best-in-class handheld mobile mapping performance for large indoor, outdoor, underground, complex, and multi-level spaces. The scanner identifies different surfaces and unique geometry in LiDAR data, which it analyses to calculate a 3D position.
Three panoramic cameras identify similarities between consecutive images to calculate the scanner’s movement through 3D space. While walking with the scanner, the IMU (Inertial Measurement Unit) senses the movement to calculate the change of position in 3D space.
“We believe that it is the right tool for the job. This is testimony to our confidence not only in the use of this technology, but to our dedication to harnessing innovation to augment our engineering skills in the digital world,” concludes Matchett.