thrust command output

简明释义

推力指令输出

英英释义

例句

1.The thrust command output was calibrated to match the specifications of the new engine model.

为了匹配新发动机型号的规格，推力指令输出进行了校准。

2.During the simulation, we monitored the thrust command output to ensure the engine performed correctly.

在模拟过程中，我们监控了推力指令输出以确保发动机正常运行。

3.Adjusting the thrust command output can significantly impact the aircraft's climb rate.

调整推力指令输出可以显著影响飞机的爬升率。

4.The pilot adjusted the settings to optimize the thrust command output for better fuel efficiency.

飞行员调整设置以优化推力指令输出，以提高燃油效率。

5.The engineers analyzed the thrust command output data to troubleshoot the performance issues.

工程师分析了推力指令输出数据，以排查性能问题。

作文

In the field of aerospace engineering, the term thrust command output plays a crucial role in the operation and control of aircraft and spacecraft. This phrase refers to the signals generated by the flight control system that dictate the amount of thrust required from the engines to achieve desired performance during various phases of flight. Understanding the thrust command output is essential for engineers and pilots alike, as it directly impacts the safety and efficiency of flight operations.The thrust command output is typically determined by several factors, including the aircraft's current speed, altitude, weight, and the desired flight path. For instance, during takeoff, the thrust command output must be maximized to ensure that the aircraft can lift off the ground safely. Conversely, during descent, the command output may need to be reduced to allow for a controlled landing. This dynamic adjustment of thrust is vital for maintaining optimal performance throughout the flight.Moreover, modern aircraft are equipped with sophisticated flight management systems that automate the generation of thrust command output. These systems utilize algorithms that process real-time data from various sensors to calculate the necessary thrust levels. By automating this process, pilots can focus on other critical aspects of flying, such as navigation and communication, while still ensuring that the aircraft operates within safe parameters.The importance of understanding thrust command output extends beyond just operational efficiency; it also encompasses safety considerations. In emergency situations, such as engine failure or severe weather conditions, pilots must be able to quickly interpret the thrust command output and make rapid adjustments to maintain control of the aircraft. A thorough comprehension of how thrust commands affect flight dynamics can be the difference between a safe landing and a catastrophic incident.Additionally, the concept of thrust command output is not limited to traditional aircraft. In the realm of space exploration, rockets and spacecraft also rely on precise thrust management to navigate through the atmosphere and into orbit. Engineers must carefully calculate the thrust command output to ensure that the spacecraft can overcome gravitational forces and achieve the necessary velocity for its mission. This requires a deep understanding of physics and engineering principles, highlighting the interdisciplinary nature of aerospace technology.In conclusion, the term thrust command output encapsulates a fundamental aspect of flight control that is critical for both aircraft and spacecraft. Its implications extend to safety, efficiency, and the overall success of flight missions. As technology continues to advance, the methods used to calculate and implement thrust command output will likely evolve, but the core principles will remain essential for the future of aviation and space exploration. Mastery of this concept is vital for anyone involved in the aerospace industry, from engineers designing cutting-edge aircraft to pilots navigating through the skies.

在航空航天工程领域，短语thrust command output在飞机和航天器的操作与控制中扮演着至关重要的角色。这个短语指的是由飞行控制系统生成的信号，这些信号指示引擎所需的推力量，以在飞行的不同阶段实现预期的性能。理解thrust command output对于工程师和飞行员来说都是至关重要的，因为它直接影响到飞行操作的安全性和效率。thrust command output通常由多个因素决定，包括飞机当前的速度、高度、重量以及期望的飞行路径。例如，在起飞过程中，thrust command output必须最大化，以确保飞机能够安全地离开地面。相反，在下降过程中，命令输出可能需要减少，以便进行控制着陆。这种推力的动态调整对保持飞行的最佳性能至关重要。此外，现代飞机配备了复杂的飞行管理系统，这些系统自动生成thrust command output。这些系统利用算法处理来自各种传感器的实时数据，以计算所需的推力水平。通过自动化这一过程，飞行员可以专注于飞行的其他关键方面，如导航和通信，同时仍然确保飞机在安全参数内运行。理解thrust command output的重要性不仅限于操作效率；它还包括安全考虑。在紧急情况下，例如引擎故障或恶劣天气条件下，飞行员必须能够快速解释thrust command output并迅速进行调整，以保持飞机的控制。对推力命令如何影响飞行动力学的透彻理解可能是安全着陆与灾难性事件之间的区别。此外，thrust command output的概念不仅限于传统飞机。在太空探索领域，火箭和航天器也依赖于精确的推力管理来穿越大气层并进入轨道。工程师必须仔细计算thrust command output，以确保航天器能够克服重力并实现其任务所需的速度。这需要对物理学和工程原理有深入的理解，突显了航空航天技术的跨学科特性。总之，短语thrust command output概括了飞行控制的一个基本方面，对于飞机和航天器至关重要。它的影响扩展到安全性、效率和飞行任务的整体成功。随着技术的不断进步，用于计算和实施thrust command output的方法可能会发展，但核心原则将继续对航空和太空探索的未来至关重要。掌握这一概念对于任何参与航空航天行业的人来说都是至关重要的，从设计尖端飞机的工程师到在天空中导航的飞行员。