constrained motion

简明释义

约束运动

英英释义

例句

1.In this simulation, we need to account for constrained motion of the vehicle due to the narrow pathway.

在这个模拟中，我们需要考虑由于狭窄通道导致的受限运动。

2.The animation features a character with constrained motion to reflect the limitations of their environment.

动画中的角色具有受限运动，以反映他们环境的限制。

3.The athlete demonstrated constrained motion during the routine, showcasing their ability to perform within tight spaces.

运动员在例行训练中展示了受限运动，展现了他们在狭小空间内表演的能力。

4.The robot's arm is designed for constrained motion to prevent it from exceeding its operational limits.

机器人的手臂设计用于受限运动，以防止其超出操作限制。

5.For safety reasons, the machinery operates under constrained motion to avoid accidents.

出于安全原因，机器在受限运动下运行，以避免事故。

作文

In the realm of physics and engineering, the concept of constrained motion plays a pivotal role in understanding how objects move under specific conditions. Constrained motion refers to the movement of an object that is restricted by certain boundaries or forces. This can include various forms of limitations, such as physical barriers, gravitational forces, or even the design of mechanical systems. Understanding constrained motion is essential for engineers and physicists alike, as it helps them predict how structures will behave under different circumstances.One of the most common examples of constrained motion can be found in the design of roller coasters. The tracks of a roller coaster are designed to guide the cars along a predetermined path. The cars can only move along this track due to the physical constraints imposed by the structure. If a roller coaster car were to somehow leave the track, it would no longer be experiencing constrained motion, and the results could be disastrous. Therefore, engineers must carefully calculate the forces acting on the cars to ensure that they remain safely within the confines of the track.Another example of constrained motion can be seen in the motion of pendulums. A pendulum swings back and forth, but its motion is constrained by the length of the string and the force of gravity. The path it takes is predictable and follows a specific arc, which is determined by these constraints. This predictable nature of constrained motion allows scientists to use pendulums in various applications, from timekeeping in clocks to experiments in physics.In robotics, constrained motion is also a critical factor to consider. When designing robotic arms, engineers must account for the limits of motion that each joint can achieve. Each joint in a robotic arm has a specific range of motion, and if the arm exceeds these limits, it could lead to mechanical failure. Thus, understanding the principles of constrained motion enables engineers to create more efficient and reliable robotic systems.Moreover, constrained motion is not limited to physical objects; it can also apply to theoretical models in mathematics and computer science. For instance, in optimization problems, solutions are often constrained by certain parameters or criteria. These constraints dictate the feasible region within which a solution can exist, making the study of constrained motion relevant across various fields.In conclusion, the understanding of constrained motion is integral to numerous disciplines, including engineering, physics, and mathematics. By recognizing the limitations imposed on moving objects, professionals can better predict outcomes and design systems that function effectively within those constraints. Whether it’s ensuring the safety of a roller coaster, the accuracy of a pendulum, or the efficiency of a robotic arm, the principles of constrained motion are fundamental to our ability to innovate and improve technology. As we continue to explore the complexities of motion, it is clear that the study of constrained motion will remain a cornerstone of scientific inquiry and practical application.

在物理和工程的领域中，受限运动的概念在理解物体在特定条件下如何运动方面起着关键作用。受限运动是指物体的运动受到某些边界或力的限制。这可以包括各种形式的限制，例如物理障碍、重力作用，甚至机械系统的设计。理解受限运动对工程师和物理学家来说都是至关重要的，因为它帮助他们预测结构在不同情况下的表现。受限运动最常见的例子之一可以在过山车的设计中找到。过山车的轨道旨在引导车辆沿预定路径移动。由于结构施加的物理约束，车辆只能沿这条轨道移动。如果过山车的车辆以某种方式离开轨道，它将不再经历受限运动，结果可能会是灾难性的。因此，工程师必须仔细计算作用在车辆上的力，以确保它们安全地保持在轨道的范围内。另一个受限运动的例子可以在摆的运动中看到。摆动来回摆动，但其运动受到绳子长度和重力的限制。它所采取的路径是可预测的，并遵循由这些约束决定的特定弧线。这种受限运动的可预测性使科学家能够在各种应用中使用摆，从钟表中的计时到物理实验。在机器人技术中，受限运动也是一个关键因素。当设计机器人手臂时，工程师必须考虑每个关节可以达到的运动限制。机器人手臂中的每个关节都有特定的运动范围，如果手臂超出了这些限制，可能会导致机械故障。因此，理解受限运动的原理使工程师能够创建更高效、更可靠的机器人系统。此外，受限运动不仅限于物理物体；它也可以应用于数学和计算机科学中的理论模型。例如，在优化问题中，解决方案通常受到某些参数或标准的限制。这些约束决定了解决方案可以存在的可行区域，使得研究受限运动在各个领域都具有相关性。总之，理解受限运动对众多学科至关重要，包括工程、物理和数学。通过认识到施加在移动物体上的限制，专业人士可以更好地预测结果并设计在这些约束内有效运作的系统。无论是确保过山车的安全、摆的准确性，还是机器人手臂的效率，受限运动的原理都是我们创新和改进技术能力的基础。随着我们继续探索运动的复杂性，显然受限运动的研究将继续成为科学探究和实际应用的基石。