aggregate motion

简明释义

组合运动;

英英释义

例句

1.The simulation showed how the aggregate motion 整体运动 of vehicles affects traffic flow.

模拟显示了车辆的aggregate motion 整体运动如何影响交通流量。

2.Understanding the aggregate motion 整体运动 of celestial bodies helps astronomers predict their paths.

理解天体的aggregate motion 整体运动有助于天文学家预测它们的轨迹。

3.The aggregate motion 整体运动 of the crowd was carefully monitored during the event for safety reasons.

在活动期间，为了安全原因，仔细监测了人群的aggregate motion 整体运动。

4.In robotics, analyzing the aggregate motion 整体运动 of multiple robots can improve coordination.

在机器人技术中，分析多个机器人的aggregate motion 整体运动可以提高协调性。

5.The researchers studied the aggregate motion 整体运动 of particles in a fluid to understand how they interact.

研究人员研究了粒子在流体中的aggregate motion 整体运动，以了解它们如何相互作用。

作文

In the realm of physics and engineering, understanding the concept of aggregate motion is crucial for analyzing the behavior of objects in motion. Aggregate motion refers to the combined movements of multiple bodies or particles that can be observed as a single entity. This concept is particularly relevant in various fields, including mechanics, robotics, and even in the study of complex systems in nature. To illustrate the importance of aggregate motion, let us consider the example of a flock of birds flying together. Each bird moves independently, yet their collective movement can be analyzed as an aggregate. When we observe a flock in flight, we notice that they often change direction simultaneously, creating a mesmerizing pattern in the sky. This synchronized behavior is a perfect representation of aggregate motion. The individual birds respond to each other's movements, leading to a cohesive group dynamic. Scientists study this phenomenon to understand how such complex behaviors arise from simple rules of interaction among individuals. Another area where aggregate motion plays a significant role is in the design of robotic systems. Engineers often create robotic swarms that mimic the behavior of natural systems, such as ants or bees. In these systems, each robot operates based on local information and interactions with its neighbors. The result is a form of aggregate motion where the swarm can perform tasks more efficiently than a single robot could achieve alone. For instance, a swarm of robots can work together to cover large areas, search for specific objects, or even build structures collaboratively. Moreover, aggregate motion is not limited to biological or mechanical systems; it also applies to social phenomena. Consider traffic flow as an example. Vehicles on a road exhibit aggregate motion as drivers react to the movements of others, leading to patterns of congestion or smooth travel. Traffic engineers analyze these patterns to improve road safety and efficiency, utilizing models that account for the aggregate motion of vehicles. Understanding aggregate motion allows scientists and engineers to predict behaviors and optimize systems. By studying the principles behind the collective dynamics of motion, we can develop better algorithms for robotics, enhance our understanding of ecological systems, and improve urban planning. As technology continues to advance, the applications of aggregate motion will only expand, paving the way for innovations that harness the power of collective behavior. In conclusion, the concept of aggregate motion serves as a vital framework for understanding how individual actions contribute to a larger system's behavior. Whether in nature, technology, or society, the principles of aggregate motion reveal the intricate connections that govern the world around us. By embracing this knowledge, we can unlock new possibilities and create solutions that reflect the complexity of collective dynamics.

在物理和工程领域，理解aggregate motion的概念对于分析运动物体的行为至关重要。Aggregate motion指的是多个物体或粒子的综合运动，可以被观察为一个单一实体。这个概念在力学、机器人技术以及自然界复杂系统的研究中尤为相关。为了说明aggregate motion的重要性，让我们考虑一群鸟一起飞翔的例子。每只鸟独立移动，但它们的集体运动可以被分析为一种聚合。 当我们观察飞行中的鸟群时，会发现它们经常会同时改变方向，在天空中形成迷人的图案。这种同步行为完美地代表了aggregate motion。个体鸟类对彼此的运动作出反应，从而导致一种凝聚的群体动态。科学家们研究这一现象，以理解如何通过个体之间简单的交互规则产生如此复杂的行为。 Aggregate motion还在机器人系统的设计中发挥着重要作用。工程师们常常创建模仿自然系统（如蚂蚁或蜜蜂）行为的机器人群体。在这些系统中，每个机器人根据局部信息和与其邻居的交互进行操作。结果是一种aggregate motion，其中群体可以比单个机器人更有效地执行任务。例如，一群机器人可以协同工作以覆盖大面积，寻找特定物体，甚至共同建造结构。 此外，aggregate motion不仅限于生物或机械系统；它也适用于社会现象。考虑交通流量作为一个例子。道路上的车辆表现出aggregate motion，因为司机对其他车辆的运动作出反应，导致拥堵或顺畅行驶的模式。交通工程师分析这些模式，以改善道路安全和效率，利用考虑到车辆aggregate motion的模型。 理解aggregate motion使科学家和工程师能够预测行为并优化系统。通过研究集体动态运动背后的原理，我们可以开发更好的机器人算法，增强对生态系统的理解，并改善城市规划。随着技术的持续进步，aggregate motion的应用将不断扩展，为利用集体行为的力量铺平道路。 总之，aggregate motion的概念作为理解个体行动如何影响更大系统行为的重要框架。无论是在自然、技术还是社会中，aggregate motion的原理揭示了支配我们周围世界的错综复杂的联系。通过接受这一知识，我们可以解锁新的可能性，创造反映集体动态复杂性的解决方案。