close loop maneuver

简明释义

闭环操作

英英释义

例句

1.During the training session, we practiced the close loop maneuver to improve our response time.

在训练课程中，我们练习了闭环机动以提高反应时间。

2.The driver performed a close loop maneuver to navigate through the tight alley.

司机进行了一个闭环机动以穿过狭窄的小巷。

3.In robotics, a close loop maneuver is essential for precise movement.

在机器人技术中，闭环机动对于精确移动至关重要。

4.The engineer explained how to implement a close loop maneuver in the control system.

工程师解释了如何在控制系统中实施闭环机动。

5.The pilot executed a close loop maneuver to avoid the incoming turbulence.

飞行员执行了一个闭环机动以避开即将到来的湍流。

作文

In the world of aviation and robotics, precision and control are paramount. One technique that highlights this importance is the close loop maneuver. This term refers to a method where a system continuously monitors its output and adjusts its input based on feedback to achieve desired outcomes. Understanding this concept can greatly enhance our grasp of various technological applications and their implications in real-world scenarios.To illustrate the significance of the close loop maneuver, let’s consider an example from aviation. Pilots often utilize autopilot systems that implement this technique. When flying an aircraft, the autopilot receives data from various sensors regarding altitude, speed, and direction. If the plane begins to drift off course, the autopilot system makes real-time adjustments to the controls, ensuring that the flight path remains stable. This constant feedback loop exemplifies how the close loop maneuver operates, enhancing safety and efficiency in air travel.Similarly, in robotics, the close loop maneuver is crucial for achieving precise movements. For instance, a robotic arm used in manufacturing must be able to adjust its position based on the items it is handling. Sensors provide feedback about the arm's location and the weight of the object being lifted. If the arm detects that it is not aligned correctly, it will make necessary adjustments to ensure that the task is completed accurately. This ability to self-correct through a close loop maneuver is what sets advanced robotics apart from simpler systems.The benefits of implementing close loop maneuvers extend beyond just aviation and robotics. In various fields such as automotive engineering, healthcare, and even environmental monitoring, feedback loops play a critical role in optimizing performance and ensuring safety. For example, modern vehicles equipped with adaptive cruise control use this technique to maintain a safe distance from other cars on the road. The system continuously assesses the speed and distance of surrounding vehicles, making real-time adjustments to the throttle and brakes as necessary. This application of the close loop maneuver not only enhances driving comfort but also significantly improves safety on the roads.Moreover, the concept of a close loop maneuver is applicable in everyday life. Consider a thermostat in a home heating system. It monitors the temperature of the room and adjusts the heating output based on the set temperature. If the room gets too cold, the thermostat signals the heater to turn on, and when the desired temperature is reached, it turns off the heater. This simple yet effective feedback mechanism ensures a comfortable living environment, demonstrating how the principles of the close loop maneuver can be found in common household devices.In conclusion, the close loop maneuver is a fundamental concept that underpins many modern technologies. By continuously monitoring outputs and adjusting inputs based on feedback, systems can achieve greater accuracy and efficiency. Whether in aviation, robotics, automotive engineering, or everyday household devices, understanding and applying the principles of close loop maneuvers can lead to significant advancements in technology and improved quality of life. As we continue to innovate and develop new systems, the importance of these feedback loops will only grow, shaping the future of various industries and enhancing our daily experiences.

在航空和机器人技术的世界中，精确性和控制力至关重要。一个突显这种重要性的技术是闭环机动。这个术语指的是一种方法，其中系统不断监测其输出，并根据反馈调整其输入，以实现期望的结果。理解这一概念可以极大地增强我们对各种技术应用及其在现实场景中的影响的掌握。为了说明闭环机动的重要性，让我们考虑一个来自航空的例子。飞行员经常利用实施这种技术的自动驾驶系统。当飞行一架飞机时，自动驾驶系统接收来自各种传感器的数据，关于高度、速度和方向。如果飞机开始偏离航线，自动驾驶系统会实时调整控制，确保飞行路径保持稳定。这种持续的反馈循环例证了闭环机动的运作方式，提高了航空旅行的安全性和效率。同样，在机器人技术中，闭环机动对实现精确运动至关重要。例如，制造中使用的机器人手臂必须能够根据其处理的物体调整位置。传感器提供关于手臂位置和被提起物体重量的反馈。如果手臂检测到未正确对齐，它将进行必要的调整，以确保任务准确完成。这种通过闭环机动自我修正的能力使先进的机器人技术与简单系统区分开来。实施闭环机动的好处超越航空和机器人技术。在汽车工程、医疗保健甚至环境监测等各个领域，反馈循环在优化性能和确保安全方面发挥着关键作用。例如，配备自适应巡航控制的现代车辆使用这种技术来保持与道路上其他汽车的安全距离。该系统不断评估周围车辆的速度和距离，根据需要实时调整油门和刹车。这种闭环机动的应用不仅提高了驾驶舒适性，还显著改善了道路安全。此外，闭环机动的概念在日常生活中也适用。考虑家用供暖系统中的恒温器。它监测房间的温度，并根据设定温度调整加热输出。如果房间变得太冷，恒温器会发出信号给加热器打开，当达到所需温度时，它会关闭加热器。这种简单而有效的反馈机制确保了舒适的居住环境，展示了闭环机动的原则如何在常见家用设备中找到应用。总之，闭环机动是许多现代技术的基本概念。通过持续监测输出并根据反馈调整输入，系统可以实现更高的准确性和效率。无论是在航空、机器人技术、汽车工程还是日常家用设备中，理解和应用闭环机动的原则都能带来技术的重大进步和生活质量的提升。随着我们继续创新和开发新系统，这些反馈循环的重要性将只会增长，塑造各个行业的未来，并增强我们的日常体验。