impulse system

简明释义

脉冲制

英英释义

例句

1.Understanding the impulse system can help businesses create effective promotional campaigns.

理解冲动系统可以帮助企业制定有效的促销活动。

2.The impulse system plays a crucial role in e-commerce, where quick decisions are often made.

在电子商务中，冲动系统起着至关重要的作用，因为往往会做出快速决策。

3.By analyzing customer behavior, we can better understand how the impulse system influences buying patterns.

通过分析客户行为，我们可以更好地理解冲动系统如何影响购买模式。

4.Retailers often design stores to trigger the impulse system in customers, encouraging them to buy more.

零售商通常设计商店以触发顾客的冲动系统，鼓励他们购买更多。

5.The new marketing strategy relies heavily on the impulse system to drive immediate purchases.

新的营销策略在很大程度上依赖于冲动系统来推动即时购买。

作文

In the realm of physics and engineering, the concept of an impulse system is fundamental to understanding how forces interact over time to produce motion. An impulse system refers to a system where a sudden force, or impulse, is applied to an object, resulting in a change in momentum. This concept is crucial in various applications, from designing vehicles to analyzing sports dynamics. To understand an impulse system, we must first grasp the relationship between force, time, and momentum. Momentum, defined as the product of an object's mass and its velocity, is a vector quantity that describes the motion of an object. When a force is applied to an object for a short duration, it imparts an impulse, which can be calculated as the product of the force and the time duration over which it acts. The greater the impulse, the larger the change in momentum will be. For example, consider a soccer player kicking a ball. The moment the player's foot strikes the ball, a significant force is applied over a brief period. This interaction constitutes an impulse system. The impulse generated by the kick propels the ball forward, changing its momentum and allowing it to travel toward the goal. Understanding this principle helps coaches and athletes optimize their techniques to maximize performance. In engineering, the application of impulse systems is evident in various designs, such as car crash tests. Engineers simulate collisions to study how vehicles respond to sudden impacts. By analyzing the impulse experienced by different components during a crash, they can improve safety features, ensuring that the forces are distributed effectively to minimize injury to passengers. Moreover, impulse systems are not limited to mechanical systems; they also apply to biological systems. For instance, when a muscle contracts, it generates an impulse that can be analyzed similarly to a physical force. Understanding how muscles work as impulse systems helps in rehabilitation and athletic training, allowing for better recovery strategies and performance enhancement. In conclusion, the study of impulse systems is essential across multiple disciplines, including physics, engineering, and biology. By understanding how sudden forces affect motion and momentum, we can enhance our knowledge and improve applications in various fields. Whether it’s optimizing a soccer kick or designing safer vehicles, the principles governing impulse systems play a vital role in shaping our understanding of motion and force interactions. As we continue to explore these concepts, we can develop innovative solutions that harness the power of impulses to create more efficient and effective systems in our everyday lives.

在物理和工程领域，冲击系统的概念对于理解力如何随时间相互作用以产生运动是基础。冲击系统指的是一个系统，在这个系统中，突然施加的力或冲击会导致物体动量的变化。这个概念在各种应用中至关重要，从设计车辆到分析运动动态。要理解冲击系统，我们首先必须掌握力、时间和动量之间的关系。动量被定义为物体的质量与其速度的乘积，是描述物体运动的矢量量。当力在短时间内施加到物体上时，它会施加一个冲击，这个冲击可以计算为力与作用时间的乘积。冲击越大，动量的变化就越大。例如，考虑一名足球运动员踢球的情景。当运动员的脚撞击球的那一刻，会在短时间内施加一个显著的力。这种相互作用构成了一个冲击系统。踢球产生的冲击推动球向前，改变其动量，使其朝着球门飞去。理解这一原理有助于教练和运动员优化他们的技术，以最大化表现。在工程学中，冲击系统的应用在各种设计中显而易见，例如汽车碰撞测试。工程师模拟碰撞以研究车辆在突然冲击下的反应。通过分析在碰撞过程中不同部件所经历的冲击，他们可以改善安全特性，确保力量有效分配，以最小化乘客的伤害。此外，冲击系统并不仅限于机械系统；它们也适用于生物系统。例如，当肌肉收缩时，它会产生一个冲击，可以类似于物理力进行分析。理解肌肉如何作为冲击系统工作，有助于康复和运动训练，使得更好的恢复策略和性能提升成为可能。总之，研究冲击系统在多个学科中都是必不可少的，包括物理学、工程学和生物学。通过理解突发力量如何影响运动和动量，我们可以增强我们的知识，并改善各个领域的应用。无论是优化足球踢法还是设计更安全的车辆，支配冲击系统的原理在塑造我们对运动和力相互作用的理解方面发挥着重要作用。随着我们继续探索这些概念，我们可以开发出利用冲击力量的创新解决方案，以在日常生活中创造更高效、更有效的系统。