propulsinal local control

简明释义

推进装置机旁控制

英英释义

例句

1.Using propulsinal local control, the drone can hover steadily while capturing high-resolution images.

通过使用推进局部控制，无人机可以稳定悬停，同时捕捉高分辨率图像。

2.The marine vehicle's propulsinal local control allows it to make quick turns without losing speed.

海洋载具的推进局部控制使其能够快速转弯而不失去速度。

3.The spacecraft's navigation system relies on propulsinal local control to adjust its trajectory during flight.

宇宙飞船的导航系统依赖于推进局部控制在飞行过程中调整其轨迹。

4.In autonomous vehicles, propulsinal local control is essential for precise maneuvering in tight spaces.

在自动驾驶汽车中，推进局部控制对于在狭小空间内的精确操控至关重要。

5.The robotics team implemented propulsinal local control to enhance the robot's ability to navigate complex environments.

机器人团队实施了推进局部控制以增强机器人在复杂环境中的导航能力。

作文

In the realm of modern engineering and technology, the concept of propulsinal local control plays a crucial role in the design and functionality of various systems. This term refers to the localized management of propulsion systems, which are essential for the movement and operation of vehicles, aircraft, and even spacecraft. Understanding propulsinal local control is vital for engineers and designers who aim to create efficient and effective propulsion mechanisms.The significance of propulsinal local control can be observed in numerous applications. For instance, in aerospace engineering, the precise control of thrust and direction is paramount for the stability and maneuverability of an aircraft. By employing propulsinal local control, engineers can ensure that each engine operates optimally, responding to changes in altitude, speed, and external conditions. This localized approach allows for fine-tuning of propulsion systems, leading to improved performance and safety.Furthermore, propulsinal local control is not limited to aviation. In the automotive industry, advancements in technology have enabled the integration of sophisticated control systems that manage the propulsion of vehicles more effectively. By utilizing sensors and real-time data analysis, these systems can adjust power output and torque distribution to enhance fuel efficiency and reduce emissions. This application of propulsinal local control demonstrates how localized management can lead to significant environmental benefits while also improving the driving experience.Moreover, the importance of propulsinal local control extends into the realm of robotics. As robots become increasingly autonomous, the ability to control their movements with precision is essential. Localized control systems allow robots to navigate complex environments by adjusting their propulsion mechanisms based on immediate feedback from their surroundings. This capability is particularly crucial in fields such as search and rescue operations, where robots must operate in unpredictable and dynamic situations.In addition to its practical applications, propulsinal local control also raises important considerations regarding system design and integration. Engineers must balance the need for localized control with the overall architecture of the propulsion system to ensure reliability and efficiency. This involves careful consideration of factors such as weight, power consumption, and the potential for failure in localized systems. By addressing these challenges, engineers can develop propulsion systems that are not only effective but also resilient.In conclusion, the concept of propulsinal local control is integral to the advancement of various technologies across multiple industries. From aerospace to automotive and robotics, the ability to manage propulsion systems locally enhances performance, safety, and efficiency. As technology continues to evolve, the principles of propulsinal local control will undoubtedly play a pivotal role in shaping the future of transportation and automation. Understanding this concept is essential for anyone involved in engineering and design, as it represents a key aspect of creating innovative solutions for complex challenges.

在现代工程和技术领域，propulsinal local control的概念在各种系统的设计和功能中发挥着至关重要的作用。这个术语指的是推进系统的局部管理，而推进系统对于车辆、飞机甚至航天器的移动和操作至关重要。理解propulsinal local control对旨在创造高效有效推进机制的工程师和设计师来说是至关重要的。propulsinal local control的重要性可以在众多应用中观察到。例如，在航空航天工程中，推力和方向的精确控制对于飞机的稳定性和机动性至关重要。通过采用propulsinal local control，工程师可以确保每台发动机都能最佳运行，及时响应高度、速度和外部条件的变化。这种局部方法允许对推进系统进行微调，从而提高性能和安全性。此外，propulsinal local control并不仅限于航空。在汽车工业中，技术的进步使得集成复杂的控制系统成为可能，这些系统能够更有效地管理车辆的推进。通过利用传感器和实时数据分析，这些系统可以调整功率输出和扭矩分配，以增强燃油效率并减少排放。这种propulsinal local control的应用展示了局部管理如何带来显著的环境效益，同时改善驾驶体验。此外，propulsinal local control的重要性还延伸到机器人领域。随着机器人变得越来越自主，精确控制其运动的能力至关重要。局部控制系统允许机器人根据周围环境的即时反馈调整其推进机制，从而在复杂环境中导航。这种能力在搜索和救援操作等领域尤为关键，因为机器人必须在不可预测和动态的情况下运作。除了其实际应用之外，propulsinal local control还提出了关于系统设计和集成的重要考虑。工程师必须平衡局部控制的需求与推进系统的整体架构，以确保可靠性和效率。这涉及到对重量、功耗和局部系统潜在故障等因素的仔细考虑。通过解决这些挑战，工程师可以开发出不仅有效而且具有韧性的推进系统。总之，propulsinal local control的概念对于推动多个行业的各种技术进步至关重要。从航空航天到汽车和机器人，局部管理推进系统的能力提升了性能、安全性和效率。随着技术的不断发展，propulsinal local control的原则无疑将在塑造运输和自动化的未来中发挥关键作用。理解这一概念对于任何参与工程和设计的人来说都是必不可少的，因为它代表了为复杂挑战创造创新解决方案的关键方面。