range of homing stage

简明释义

自导段航程

英英释义

例句

1.We need to calibrate the sensors to accurately determine the range of homing stage for the satellite.

我们需要校准传感器，以准确确定卫星的归航阶段范围。

2.The drone can operate within a range of homing stage that allows it to return to its base from several kilometers away.

这款无人机可以在一个归航阶段范围内操作，使其能够从几公里外返回基地。

3.The range of homing stage is crucial for the autonomous vehicle to navigate back home after completing its tasks.

对于自动驾驶车辆来说，归航阶段范围对其在完成任务后导航回家至关重要。

4.To ensure safety, the range of homing stage for the robot must be tested before deployment.

为了确保安全，必须在部署之前测试机器人的归航阶段范围。

5.Adjusting the range of homing stage can improve the efficiency of the delivery drones.

调整归航阶段范围可以提高快递无人机的效率。

作文

In the world of robotics and artificial intelligence, the concept of navigation is paramount. One of the most fascinating aspects of this field is the range of homing stage, which refers to the various phases that a robotic system goes through to locate and return to a specific point of origin. This multi-faceted approach not only enhances efficiency but also ensures that robots can operate autonomously in complex environments. Understanding the range of homing stage is crucial for developers and engineers who aim to create systems that can adapt to changing conditions and unexpected obstacles.To begin with, the first phase in the range of homing stage is the initial detection of the target location. This is where sensors and algorithms come into play. Robots equipped with GPS, LIDAR, or visual recognition systems can pinpoint their starting position and the desired destination. The accuracy of this phase is vital, as it sets the foundation for the subsequent stages. If a robot miscalculates its location, it may end up lost or unable to return home.Once the target has been identified, the second phase involves planning the route. In this stage, the robot analyzes various pathways, considering factors such as obstacles, terrain, and potential hazards. The range of homing stage encompasses different strategies for navigation, including direct paths, detours around obstacles, and even the use of machine learning to improve future navigation based on past experiences. This adaptability is what makes modern robotics so exciting and effective.The third phase is execution, where the robot begins its journey back to the origin. During this stage, real-time adjustments are often necessary. For instance, if an unexpected obstacle appears, the robot must quickly reassess its route and make corrections. This dynamic aspect of the range of homing stage underscores the importance of having sophisticated algorithms that can process information rapidly and make decisions in real time.Finally, the last phase is the arrival at the target location. This stage is not merely about reaching the destination; it also involves recognizing that the robot has successfully returned to its starting point. The range of homing stage concludes with the robot confirming its position and potentially preparing for the next task. This feedback loop is essential for continuous improvement, allowing the system to learn from each journey.In conclusion, the range of homing stage represents a critical framework in the development of autonomous robots. Each phase—from detection to execution and finally arrival—plays a significant role in ensuring that robots can navigate effectively and efficiently. As technology continues to advance, understanding these stages will be crucial for anyone involved in robotics, paving the way for more intelligent and capable machines that can operate seamlessly in our world. The implications of mastering the range of homing stage extend beyond just robotics; they touch on areas like logistics, transportation, and even space exploration, where precise navigation is essential for success.

在机器人和人工智能的世界中，导航的概念至关重要。这个领域最迷人的方面之一是归航阶段的范围，它指的是机器人系统为定位和返回特定起点而经历的各种阶段。这种多方面的方法不仅提高了效率，还确保机器人能够在复杂环境中自主操作。理解归航阶段的范围对于旨在创建能够适应变化条件和意外障碍的系统的开发者和工程师至关重要。首先，归航阶段的范围中的第一阶段是目标位置的初步检测。在这一阶段，传感器和算法发挥着重要作用。配备GPS、激光雷达或视觉识别系统的机器人可以准确定位其起始位置和所需目的地。此阶段的准确性至关重要，因为它为后续阶段奠定了基础。如果机器人错误计算了其位置，它可能会迷失方向或无法返回家园。一旦目标被识别，第二阶段涉及规划路线。在这一阶段，机器人分析各种路径，考虑障碍物、地形和潜在危险等因素。归航阶段的范围包含不同的导航策略，包括直接路径、绕过障碍物的绕行，甚至利用机器学习根据过去的经验改善未来的导航。这种适应性使现代机器人技术变得如此激动人心和有效。第三个阶段是执行，机器人开始其返回原点的旅程。在这一阶段，实时调整往往是必要的。例如，如果出现意外障碍，机器人必须迅速重新评估其路线并进行修正。归航阶段的范围的这种动态特性强调了拥有能够快速处理信息并实时做出决策的复杂算法的重要性。最后，最后一个阶段是到达目标位置。这个阶段不仅仅是到达目的地；它还涉及到识别机器人成功返回其起点。归航阶段的范围以机器人确认其位置并可能为下一个任务做好准备而结束。这个反馈循环对持续改进至关重要，使系统能够从每次旅程中学习。总之，归航阶段的范围代表了自主机器人发展的关键框架。从检测到执行，再到最终的到达，每个阶段在确保机器人能够有效和高效导航方面都发挥着重要作用。随着技术的不断进步，理解这些阶段对于任何参与机器人技术的人来说都将至关重要，为更智能、更强大的机器铺平道路，使其能够在我们的世界中无缝运行。掌握归航阶段的范围的意义不仅限于机器人技术；它还涉及物流、运输甚至太空探索等领域，在这些领域中，精确的导航对于成功至关重要。