The core problem that “Reflate” addresses is what engineers call . A standard laser assumes the material is perfectly flat. But a 0.5mm warp in a piece of plywood can mean the difference between a clean engrave and a defocused, burnt mess. Before Reflation, the solution was expensive rotary attachments or manual refocusing—a halting of the workflow. Reflate proposes a dynamic solution: the machine’s camera and sensors do not just see the material; they map it. 2. Reflation as Dynamic Topography To “reflate” in the xTool ecosystem implies a process of non-contact surface reconstruction . The machine likely uses a structured light sensor or an AI-driven camera array to scan the target object before the laser fires.
xTool is reframing the laser from a tool of destruction (burning away material) to a tool of revelation. By reflecting on the surface—literally measuring how light bounces back—the machine determines the density, moisture content, and grain of the wood. It then reflates the power curve to suit that specific pixel. xtool reflate
The algorithm builds a probabilistic depth map. Where the material dips, the laser adjusts its focal length in real-time. Where the material rises, the power modulates to prevent scorching. But the true genius of "Reflate" goes deeper. It is not just height mapping ; it is . If a previous engraving left a residue that changes the surface reflectivity, the Reflate protocol adjusts the beam’s dwell time. The core problem that “Reflate” addresses is what