maneuverability and control characteristics

简明释义

运转及操纵特性

英英释义

例句

1.In racing, a car's maneuverability and control characteristics can determine its performance on the track.

在赛车中，汽车的机动性和控制特性可以决定其在赛道上的表现。

2.The new drone has improved maneuverability and control characteristics that allow it to navigate tight spaces easily.

这款新无人机具有改进的机动性和控制特性，使其能够轻松穿越狭小空间。

3.The pilot was impressed by the maneuverability and control characteristics of the new fighter jet.

飞行员对新战斗机的机动性和控制特性印象深刻。

4.Engineers are testing the maneuverability and control characteristics of the new robotic arm.

工程师们正在测试新型机器人手臂的机动性和控制特性。

5.The yacht's maneuverability and control characteristics make it suitable for both racing and leisure sailing.

这艘游艇的机动性和控制特性使其适合竞赛和休闲航行。

作文

In the world of aviation and automotive engineering, the terms maneuverability and control characteristics are crucial for assessing the performance of vehicles. These attributes determine how effectively a vehicle can respond to the driver's or pilot's inputs, especially in dynamic environments. Understanding these characteristics is essential not only for manufacturers but also for users who rely on these machines for safety and efficiency.Maneuverability refers to the ability of a vehicle to change its direction quickly and efficiently. This is particularly important in scenarios where rapid adjustments are necessary, such as during emergency situations or in tight spaces. For example, a fighter jet must possess exceptional maneuverability and control characteristics to execute complex aerial maneuvers that can evade enemy fire or engage in dogfights. Similarly, a sports car needs high maneuverability to navigate sharp turns at high speeds without losing stability.On the other hand, control characteristics pertain to how well a vehicle maintains its intended path or trajectory. This includes aspects such as steering responsiveness, stability during acceleration and deceleration, and overall handling. A vehicle with superior control characteristics will feel more predictable and manageable to the driver, enhancing the driving experience and providing a sense of confidence. For instance, a luxury sedan may prioritize comfort and smooth control characteristics, allowing passengers to enjoy a serene ride even on uneven roads.The interplay between maneuverability and control characteristics is vital in designing vehicles that meet specific needs. Engineers must balance these two aspects to create vehicles that are not only fast and agile but also stable and easy to handle. In motorsports, teams often fine-tune their cars' suspension systems to optimize these traits, ensuring that drivers can push their limits while maintaining control over their vehicles.Moreover, advancements in technology have significantly impacted the maneuverability and control characteristics of modern vehicles. The integration of electronic stability control systems, anti-lock braking systems, and advanced aerodynamics has transformed how vehicles respond to driver inputs. For example, many contemporary sports cars come equipped with adaptive suspension systems that automatically adjust to driving conditions, enhancing both maneuverability and control.In conclusion, maneuverability and control characteristics are essential components that define the performance and safety of vehicles in various contexts. Whether in aviation, automotive racing, or everyday transportation, understanding these characteristics helps engineers design better vehicles and allows users to make informed choices. As technology continues to evolve, we can expect even greater advancements in these areas, leading to safer and more efficient means of transportation for everyone.

在航空和汽车工程的世界中，术语机动性和控制特性对于评估车辆性能至关重要。这些属性决定了车辆对驾驶员或飞行员输入的反应能力，尤其是在动态环境中。理解这些特性对于制造商和依赖这些机器进行安全和高效操作的用户而言都是必不可少的。机动性指的是车辆快速有效地改变方向的能力。这在紧急情况下或狭小空间中迅速调整时尤为重要。例如，战斗机必须具备卓越的机动性和控制特性，以执行复杂的空中机动，从而躲避敌方火力或参与空战。同样，跑车需要高机动性，以便在高速下安全地通过急转弯而不失去稳定性。另一方面，控制特性涉及到车辆保持其预定路径或轨迹的能力。这包括转向响应、加速和减速过程中的稳定性以及整体操控性等方面。一辆具有优越控制特性的车辆会让驾驶者感到更可预测和易于管理，从而提升驾驶体验并增强信心。例如，一款豪华轿车可能会优先考虑舒适性和顺畅的控制特性，使乘客即使在崎岖不平的道路上也能享受宁静的乘坐体验。机动性和控制特性之间的相互作用在设计满足特定需求的车辆时至关重要。工程师必须平衡这两个方面，以创造出不仅快速灵活，而且稳定易操控的车辆。在赛车运动中，车队通常会微调汽车的悬挂系统，以优化这些特性，确保驾驶者在保持对车辆控制的同时能够挑战极限。此外，技术的进步对现代车辆的机动性和控制特性产生了重大影响。电子稳定控制系统、反锁刹车系统和先进的空气动力学的整合改变了车辆对驾驶员输入的响应方式。例如，许多现代跑车配备了自适应悬挂系统，能够根据驾驶条件自动调整，从而提高机动性和控制性。总之，机动性和控制特性是定义各种背景下车辆性能和安全性的基本组成部分。无论是在航空、汽车赛事还是日常交通中，理解这些特性有助于工程师设计更好的车辆，也使用户能够做出明智的选择。随着技术的不断发展，我们可以期待在这些领域取得更大的进步，从而为每个人提供更安全、更高效的交通工具。