delay of swing-response

简明释义

应舵时间

英英释义

Delay of swing-response refers to the time lag between the initiation of a swing movement and the actual response or completion of that swing, often observed in mechanical systems or in human motion.

摆动响应的延迟是指摆动动作开始与实际响应或完成之间的时间滞后,通常在机械系统或人类运动中观察到。

例句

1.The engineer noted a significant delay of swing-response in the machinery when it was first activated.

工程师注意到机器启动时存在显著的摆动响应延迟

2.The delay of swing-response in this model is longer than expected, requiring further adjustments.

该模型中的摆动响应延迟比预期要长,需要进一步调整。

3.To improve efficiency, we need to minimize the delay of swing-response in the robotic arm.

为了提高效率,我们需要尽量减少机器人手臂的摆动响应延迟

4.During the test, we observed a delay of swing-response that could affect the overall performance of the system.

在测试过程中,我们观察到有可能影响系统整体性能的摆动响应延迟

5.The pilot reported a delay of swing-response during the flight maneuvers, which raised safety concerns.

飞行员在飞行机动过程中报告了摆动响应延迟,这引发了安全隐患。

作文

In the realm of physics and engineering, the term delay of swing-response refers to the time lag observed in the response of a swinging object or system when subjected to external forces. This phenomenon is particularly significant in systems where oscillation plays a crucial role, such as pendulums, swings, and various mechanical devices. Understanding the delay of swing-response can help engineers design more efficient systems that minimize energy loss and enhance performance.When a force is applied to a swinging object, it does not respond instantaneously. Instead, there is a brief period during which the object remains in its original position before beginning to move. This delay can be attributed to several factors, including inertia, damping, and the characteristics of the material involved. Inertia, for instance, is the tendency of an object to resist changes in its state of motion, which means that a swinging object will take some time to start moving in response to an applied force.Moreover, damping plays a vital role in the delay of swing-response. Damping refers to the resistance encountered by a swinging object as it moves through a medium, such as air or water. This resistance can slow down the object's response to external forces, resulting in a noticeable delay. For example, a swing in a playground may take longer to respond to a push if there are strong winds or if the swing is made of a heavy material that resists motion.The delay of swing-response is not just a theoretical concept; it has practical implications in various fields. In architecture, for instance, understanding this delay can aid in designing buildings that can withstand earthquakes. Engineers must consider how long it will take for a structure to respond to seismic waves and ensure that it can absorb those forces effectively without collapsing.In robotics, the delay of swing-response is crucial for programming movements. Robotic arms, for example, must account for the time it takes for them to swing from one position to another. If the delay is not accurately calculated, the robot may overshoot or undershoot its target, leading to errors in operation. Thus, engineers must carefully analyze the dynamics of the robotic system to optimize its performance.Additionally, the delay of swing-response can be observed in everyday life. When a person pushes a child on a swing, there is a noticeable delay before the swing begins to move forward. This delay can affect the timing of subsequent pushes, as the person must anticipate when to apply additional force to maintain the swing's momentum. Understanding this delay can enhance the experience of swinging for both the child and the pusher, ensuring a smoother and more enjoyable ride.In conclusion, the delay of swing-response is a critical concept in understanding the dynamics of swinging objects and systems. By studying this phenomenon, engineers and scientists can create more efficient designs, improve safety measures, and enhance user experiences. Whether in architecture, robotics, or everyday activities, recognizing and accounting for this delay can lead to better outcomes and innovations in various fields. As we continue to explore the intricacies of motion and response, the importance of understanding the delay of swing-response cannot be overstated.

在物理和工程领域,短语延迟摆动响应指的是在施加外力时,摆动物体或系统的反应中观察到的时间滞后。这种现象在振荡起着至关重要作用的系统中尤其重要,例如摆锤、秋千和各种机械设备。理解延迟摆动响应可以帮助工程师设计更高效的系统,从而最小化能量损失并提高性能。当外力施加到摆动物体上时,它并不会立即作出反应。相反,在物体开始移动之前,会有一个短暂的时间段。在此期间,物体保持在其原始位置。这种延迟可以归因于几个因素,包括惯性、阻尼和所涉及材料的特性。例如,惯性是物体抵抗运动状态变化的倾向,这意味着摆动物体在受到外力影响时需要一些时间才能开始移动。此外,阻尼在延迟摆动响应中也起着至关重要的作用。阻尼是指摆动物体在通过介质(如空气或水)移动时遇到的阻力。这种阻力会减缓物体对外力的反应,从而导致明显的延迟。例如,如果秋千在玩耍场中受到强风的影响,或者秋千由重材料制成以抵抗运动,那么它可能需要更长的时间来响应推动。延迟摆动响应不仅仅是一个理论概念;它在各个领域都有实际意义。在建筑学中,理解这一延迟可以帮助设计能够抵御地震的建筑。工程师必须考虑结构对地震波响应所需的时间,并确保其能够有效吸收这些力量而不倒塌。在机器人技术中,延迟摆动响应对于编程运动至关重要。例如,机器人手臂必须考虑从一个位置摆动到另一个位置所需的时间。如果延迟没有准确计算,机器人可能会超出或未达到目标,导致操作错误。因此,工程师必须仔细分析机器人系统的动力学,以优化其性能。此外,延迟摆动响应也可以在日常生活中观察到。当一个人推孩子在秋千上时,会明显感受到秋千开始前进的延迟。这种延迟可能会影响后续推动的时机,因为推动者必须预判何时施加额外的力量以保持秋千的动量。理解这一延迟可以提升孩子和推动者的秋千体验,确保更流畅、更愉快的乘坐。总之,延迟摆动响应是理解摆动物体和系统动态的重要概念。通过研究这一现象,工程师和科学家可以创造更高效的设计,提高安全措施,并增强用户体验。无论是在建筑、机器人技术还是日常活动中,认识并考虑这种延迟都可以带来更好的结果和各个领域的创新。随着我们继续探索运动和反应的复杂性,理解延迟摆动响应的重要性不容忽视。