automatic track follower

简明释义

航线自动跟踪器

英英释义

例句

1.Farmers are using drones equipped with an automatic track follower to monitor crop health effectively.

农民们使用配备有自动轨道跟随器的无人机有效监测作物健康。

2.The new train model features an automatic track follower that enhances safety by keeping the train aligned on the tracks.

新型火车模型配备了一个自动轨道跟随器，通过保持火车在轨道上的对齐来增强安全性。

3.The automatic track follower technology is being integrated into autonomous vehicles for improved navigation.

为了提高导航精度，自动轨道跟随器技术正在被整合到自主驾驶车辆中。

4.The automatic track follower in the model train allows it to stay on course even during sharp turns.

模型火车中的自动轨道跟随器使其即使在急转弯时也能保持在轨道上。

5.With the automatic track follower, the robotic vehicle can navigate complex terrains without human intervention.

借助于自动轨道跟随器，机器人车辆可以在复杂地形中无需人工干预地导航。

作文

In the world of robotics and automation, the term automatic track follower refers to a system or device that can autonomously follow a predetermined path or track without human intervention. This technology is particularly useful in various applications, including manufacturing, agriculture, and transportation. By utilizing sensors and algorithms, an automatic track follower can navigate its environment, adjust its trajectory, and maintain its position on the designated path. One of the most common examples of an automatic track follower is seen in automated guided vehicles (AGVs) used in warehouses and factories. These vehicles are equipped with sensors that detect the tracks laid out on the floor, allowing them to transport goods from one location to another efficiently. The precision and reliability of an automatic track follower significantly enhance operational efficiency, reduce labor costs, and minimize human error. Moreover, in agriculture, the use of automatic track followers has revolutionized farming practices. Tractors and other farming equipment can now be designed to follow specific paths in fields, ensuring optimal planting, fertilizing, and harvesting processes. This not only saves time but also increases crop yields by ensuring that seeds are planted at the correct depth and spacing. The integration of GPS technology with automatic track followers allows farmers to achieve unprecedented accuracy in their operations. The principles behind an automatic track follower involve several key components, including sensors, control systems, and actuators. Sensors may include infrared, ultrasonic, or laser-based devices that help the machine perceive its surroundings and determine its position relative to the track. The control system processes the data from these sensors and makes real-time decisions about how to adjust the machine’s movement. Finally, actuators translate these decisions into physical actions, steering the vehicle or adjusting its speed as necessary. As technology continues to advance, the capabilities of automatic track followers are expanding. Innovations such as machine learning and artificial intelligence are being integrated into these systems, allowing them to learn from their environment and improve their performance over time. For instance, an automatic track follower could adapt to changes in the track layout or respond to unexpected obstacles, enhancing its versatility and effectiveness. In conclusion, the automatic track follower represents a significant leap forward in the field of automation and robotics. Its ability to autonomously navigate predefined paths has transformed industries ranging from manufacturing to agriculture. As this technology continues to evolve, we can expect even greater advancements that will further streamline processes and enhance productivity across various sectors. Understanding the functionality and applications of an automatic track follower is crucial for anyone interested in the future of automation and its impact on our daily lives.

在机器人和自动化的世界中，术语自动轨道追踪器指的是一种系统或设备，它可以在没有人类干预的情况下自主跟随预定的路径或轨道。这项技术在制造、农业和交通等各种应用中尤为有用。通过利用传感器和算法，自动轨道追踪器能够导航其环境，调整其轨迹，并保持在指定路径上的位置。最常见的自动轨道追踪器示例是在仓库和工厂中使用的自动导引车（AGV）。这些车辆配备有传感器，可以检测地面上铺设的轨道，从而高效地将货物从一个地点运输到另一个地点。自动轨道追踪器的精确性和可靠性显著提高了操作效率，降低了劳动成本，并最小化了人为错误。此外，在农业中，自动轨道追踪器的使用彻底改变了农业实践。现在，拖拉机和其他农业设备可以设计成在田间沿特定路径行驶，从而确保最佳的播种、施肥和收割过程。这不仅节省了时间，还通过确保种子以正确的深度和间距播种来增加作物产量。将GPS技术与自动轨道追踪器相结合，使农民能够在操作中实现前所未有的精确度。自动轨道追踪器背后的原理涉及几个关键组件，包括传感器、控制系统和执行器。传感器可能包括红外线、超声波或基于激光的设备，帮助机器感知其周围环境并确定其相对于轨道的位置。控制系统处理来自这些传感器的数据，并实时做出关于如何调整机器运动的决策。最后，执行器将这些决策转化为物理动作，根据需要操控车辆或调整其速度。随着技术的不断进步，自动轨道追踪器的能力也在不断扩展。机器学习和人工智能等创新正在被集成到这些系统中，使它们能够从环境中学习并随着时间的推移改善其性能。例如，自动轨道追踪器可以适应轨道布局的变化或对意外障碍做出反应，从而增强其多功能性和有效性。总之，自动轨道追踪器代表了自动化和机器人领域的一次重大飞跃。它自主导航预定义路径的能力已经改变了从制造到农业的多个行业。随着这项技术的不断发展，我们可以期待更大的进步，这将进一步简化流程并提高各个行业的生产力。了解自动轨道追踪器的功能和应用，对于任何对自动化未来及其对我们日常生活影响感兴趣的人来说都是至关重要的。