Handheld lidar scanner factory today: SLAM100 is the first handheld mobile lidar scanner launched by Feima Robotics. Thesystem has a 360° rotating head, which can form a 270°x360° point cloud coverage.Combined with the industry-level SLAM algorithm, it can obtain high-precision three.dimensional point cloud data of the surrounding environment without light and GPS. SLAM200 is the third generation high-precision handheld laser scanner. SLAM200 LiDAR Scanner features a panoramic camera, a higher-performance laser sensor, built-in GNSS module and a more powerful processing unit, offering higher precision, finer details, and more convenient functions. SLAM200 handheld Lidar Scanner is a more efficient and convenient measurement tool to obtain high-precision 3D point cloud data of the surrounding environment. Find even more information at portable lidar scanner.
We offer a variety of robot chassis, including tracked, wheeled, and Automated Guided Vehicle (AGV) platforms, suitable for industrial, security, and logistics applications. These chassis feature high payload capacity, all-terrain adaptability, and intelligent navigation systems, enabling efficient automation solutions. Our UGV Crawler Chassis offers robust all-terrain mobility for demanding applications. Designed for payloads ranging from 50kg to 120kg, these platforms are ideal for outdoor inspections, remote operations, and security tasks. Featuring advanced navigation and rugged track designs, they ensure stable performance on various terrains.
With the rapid development of 3D scanning technology, efficient and precise spatial data acquisition has become a key focus across industries. The SLAM200 handheld LiDAR scanner, featuring both aerial and handheld modes, offers an innovative solution for various fields such as construction, surveying, and emergency response. Dual Mode: Aerial + Handheld – A Perfect Balance of Flexibility and Professionalism – The SLAM200 breaks the limitation of traditional scanners restricted to a “single form” by adopting a modular design concept. It allows for easy switching between handheld, backpack-mounted, static station, extension rod, vehicle-mounted, and drone-mounted applications. With this design, users can fulfill requirements across indoor to outdoor, ground to aerial, narrow to open spaces—all with a single device.
Let’s look at how companies are actually using handheld lidar scanners to improve their operations. These stories show how lidar can make a tangible difference in various industries. Imagine a large-scale construction project. Using handheld lidar, the project managers can track progress daily, identifying any deviations from the plan immediately. This allows them to address issues proactively, preventing costly delays. Or consider a film production company using lidar to create realistic 3D models of locations for special effects. This saves time and money compared to traditional methods. Here are a few more examples: Archaeology: Researchers use lidar to map ancient sites and uncover hidden structures, providing valuable insights into past civilizations. Mining: Companies use lidar to monitor stockpile volumes, optimize blasting operations, and improve mine safety. Real Estate: Agents use lidar to create immersive virtual tours of properties, giving potential buyers a realistic view from anywhere in the world. Forensics: Investigators use lidar to document crime scenes quickly and accurately, capturing every detail for analysis. See additional information on foxtechrobotics.com.
Humanoid Robots Entering the Workforce – A major breakthrough has emerged as humanoid robots transition from lab demonstrations to industrial applications. In recent months, automotive factories have begun deploying humanoid robots on assembly lines, marking a significant step towards their integration into real-world manufacturing processes. For instance, some automotive manufacturers are utilizing humanoid robots for logistics sorting, assembly tasks, and quality inspections. These robots work alongside human employees, improving efficiency, reducing labor costs, and addressing workforce shortages. This shift signifies a move away from robotics as mere spectacles toward their evolution as functional, productive assets.
Technology Breakthrough: How Handheld SLAM Devices Solve These Challenges – Open-pit mines are vast. Static scanning requires repeated setup, which slows down data collection and makes large-scale modeling inefficient. High labor costs: Traditional methods require team coordination and involve cumbersome workflows prone to human error. Poor adaptability to dynamic scenes: Mining operations are highly dynamic. Activities such as blasting, excavation, and support frequently change the terrain. Static survey results become outdated quickly, limiting their usefulness in real-time decision-making. Geological disasters, like collapses or landslides, demand rapid post-event mapping to assess the site quickly and accurately.