I. Working principle
The 360° laser obstacle avoidance detection system of the E10 Tuskrobots is mainly based on laser radar technology. Laser radar calculates the distance and position information between the robot and the obstacle by emitting laser beams to the surrounding environment and receiving the signals reflected by these laser beams after encountering obstacles. This process usually involves the following steps:
The laser radar emits pulsed or continuous laser beams to the surrounding environment. The laser beams will be reflected back after encountering obstacles and captured by the laser radar receiver. The receiver converts the received signals into electrical signals and calculates the distance and position information between the robot and the obstacle through algorithms. Based on the calculated distance and position information, the robot uses algorithms to determine whether it needs to adjust its route to avoid collisions with obstacles.
2. Detection range
The 360° laser obstacle avoidance detection system of the E10 Tuskrobots has a wide detection range that can cover the full range of space around the robot. This means that the robot can accurately sense the existence of surrounding obstacles in various complex environments, so as to make timely obstacle avoidance decisions. The specific detection range may vary depending on factors such as the robot model, lidar performance, and environmental conditions. But generally speaking, the detection range of the system is sufficient to meet the needs of industrial handling scenarios.
3. Detection Accuracy
The 360° laser obstacle avoidance detection system of the E10 Tuskrobots performs well in detection accuracy. This is due to the high-precision measurement capability of the lidar and advanced algorithm processing. Through precise measurement and calculation, the system can accurately determine the distance and position relationship between the robot and the obstacle, thereby ensuring that the robot can accurately avoid obstacles and avoid collisions during movement. The specific accuracy level may vary depending on factors such as the robot model, lidar performance, and environmental conditions. But generally speaking, the detection accuracy of the system is sufficient to meet the safety and accuracy requirements of industrial handling robots.