maneuvering control system

简明释义

机动操纵系统

英英释义

例句

1.Engineers are testing the maneuvering control system on the prototype to ensure it can handle extreme conditions.

工程师们正在测试原型上的机动控制系统，以确保它能够应对极端条件。

2.The maneuvering control system in this drone enhances its stability and precision during flight.

这款无人机中的机动控制系统增强了其飞行过程中的稳定性和精确性。

3.During the simulation, the maneuvering control system demonstrated its ability to perform complex aerial maneuvers.

在模拟过程中，机动控制系统展示了其执行复杂空中机动的能力。

4.The new fighter jet is equipped with an advanced maneuvering control system that allows for greater agility in combat.

这款新型战斗机配备了先进的机动控制系统，使其在战斗中具有更大的灵活性。

5.The ship's maneuvering control system allows it to navigate through tight spaces with ease.

这艘船的机动控制系统使其能够轻松地在狭窄空间中航行。

作文

In the realm of modern technology, the term maneuvering control system plays a pivotal role, particularly in the fields of aerospace, robotics, and maritime navigation. A maneuvering control system is essentially a sophisticated mechanism that enables an object, be it an aircraft, a spacecraft, or a ship, to change its position and orientation efficiently and accurately. This system is crucial for ensuring that these vehicles can perform complex movements while maintaining stability and safety.To understand the significance of a maneuvering control system, one must first consider the challenges involved in navigating through various environments. For instance, an aircraft must contend with changing wind patterns, atmospheric pressure, and other external forces that can affect its flight path. Similarly, a ship must navigate through turbulent waters, avoiding obstacles and adjusting to currents. In such scenarios, a reliable maneuvering control system becomes indispensable.One of the key components of a maneuvering control system is its ability to process real-time data from various sensors. These sensors gather information about the vehicle's current state, including its speed, altitude, orientation, and environmental conditions. The maneuvering control system then uses this data to calculate the necessary adjustments required to achieve the desired movement. This involves complex algorithms and computations that ensure the vehicle can respond swiftly and accurately to any changes in its environment.Moreover, the design of a maneuvering control system often incorporates advanced technologies such as artificial intelligence and machine learning. These technologies enable the system to learn from past experiences and improve its performance over time. For example, in autonomous vehicles, the maneuvering control system can adapt its strategies based on previous navigation attempts, enhancing its ability to make decisions in unfamiliar situations.The importance of a well-functioning maneuvering control system cannot be overstated, especially in critical applications such as space exploration. When sending spacecraft to distant planets, engineers rely heavily on these systems to ensure that the craft can execute precise maneuvers during its journey. Any miscalculation could result in catastrophic failures or loss of mission objectives. Therefore, rigorous testing and validation of the maneuvering control system are essential steps in the development process.In conclusion, the maneuvering control system is a fundamental aspect of modern transportation and exploration technologies. Its ability to facilitate complex movements and maintain stability under various conditions makes it invaluable across different industries. As technology continues to advance, we can expect further innovations in maneuvering control systems that will enhance our capabilities in navigating the skies, seas, and even outer space. Understanding and mastering the principles behind these systems will be crucial for future engineers and scientists as they develop the next generation of vehicles and exploration tools.

在现代科技领域，术语机动控制系统扮演着关键角色，尤其是在航空航天、机器人技术和海洋导航等领域。机动控制系统本质上是一种复杂的机制，使得物体（无论是飞机、航天器还是船只）能够高效且准确地改变其位置和方向。该系统对于确保这些交通工具能够在保持稳定性和安全性的同时执行复杂的运动至关重要。要理解机动控制系统的重要性，首先必须考虑在各种环境中导航所面临的挑战。例如，飞机必须应对不断变化的风速、气压和其他外部力量，这些力量会影响其飞行路径。类似地，船只也必须在波涛汹涌的水域中航行，避开障碍物并调整自身以适应水流。在这种情况下，可靠的机动控制系统变得不可或缺。机动控制系统的一个关键组成部分是其处理来自各种传感器的实时数据的能力。这些传感器收集有关交通工具当前状态的信息，包括其速度、高度、方向和环境条件。然后，机动控制系统利用这些数据计算实现所需运动所需的调整。这涉及复杂的算法和计算，以确保交通工具能够迅速而准确地响应环境中的任何变化。此外，机动控制系统的设计通常结合了先进的技术，如人工智能和机器学习。这些技术使系统能够从过去的经验中学习，并随着时间的推移提高其性能。例如，在自动驾驶车辆中，机动控制系统可以根据之前的导航尝试调整其策略，从而增强其在不熟悉情况下做出决策的能力。良好运作的机动控制系统的重要性不容小觑，尤其是在航天探索等关键应用中。当向遥远的行星发送航天器时，工程师们非常依赖这些系统，以确保航天器在旅途中能够执行精确的机动。任何计算错误都可能导致灾难性的失败或任务目标的丧失。因此，对机动控制系统进行严格的测试和验证是开发过程中的重要步骤。总之，机动控制系统是现代交通和探索技术的一个基本方面。它能够在各种条件下促进复杂运动并保持稳定性，使其在不同产业中具有不可替代的价值。随着科技的不断进步，我们可以期待在机动控制系统方面进一步创新，这将增强我们在天空、海洋甚至外太空中导航的能力。理解和掌握这些系统背后的原理对于未来的工程师和科学家来说，将是开发下一代交通工具和探索工具的关键。