wave excitation

简明释义

波干扰

英英释义

例句

1.Understanding wave excitation 波激励 is crucial for developing effective coastal defenses.

理解<波激励>对开发有效的海岸防御至关重要。

2.Researchers measured the wave excitation 波激励 effects on buoyancy in their experiments.

研究人员在实验中测量了<波激励>对浮力的影响。

3.Engineers must consider wave excitation 波激励 when designing offshore platforms.

工程师在设计海上平台时必须考虑<波激励>。

4.The simulation model included parameters for wave excitation 波激励 to predict structural responses.

模拟模型包含了<波激励>的参数，以预测结构响应。

5.The study focused on the effects of wave excitation 波激励 on marine structures.

这项研究集中在<波激励>对海洋结构的影响。

作文

In the field of physics and engineering, understanding the concept of wave excitation is crucial for analyzing various systems. wave excitation refers to the process by which a wave is generated or induced in a medium due to an external force or influence. This phenomenon can be observed in numerous applications, ranging from mechanical systems to electromagnetic fields. For instance, when a guitar string is plucked, the energy from the plucking motion causes the string to vibrate, resulting in sound waves being created. This is a practical example of wave excitation, where the initial action leads to a series of oscillations that propagate through the air as sound. The significance of wave excitation extends beyond musical instruments; it plays a pivotal role in engineering disciplines such as structural dynamics and acoustics. Engineers often need to consider how structures respond to various types of excitations, including seismic waves during an earthquake or wind-induced vibrations in tall buildings. By understanding wave excitation, engineers can design structures that withstand these forces, ensuring safety and durability. Moreover, wave excitation is not limited to physical structures but is also relevant in the realm of electromagnetic waves. In telecommunications, for example, antennas are designed to generate and transmit radio waves through wave excitation. The principles governing this excitation are essential for optimizing signal strength and clarity, which are vital for effective communication. Another fascinating area where wave excitation is applicable is in the study of ocean waves. The interaction between wind and water generates waves, a classic example of wave excitation in nature. Understanding this process is critical for predicting weather patterns, designing ships, and even harnessing wave energy as a renewable resource. Furthermore, the study of wave excitation is essential in the medical field, particularly in ultrasound technology. Ultrasound machines utilize wave excitation to create images of internal organs by sending high-frequency sound waves into the body and analyzing the echoes that return. This non-invasive technique has revolutionized diagnostics and is a testament to the importance of understanding wave behavior. In conclusion, the concept of wave excitation is integral to various scientific and engineering domains. Whether it is in the context of music, structural integrity, telecommunications, oceanography, or medicine, wave excitation serves as a fundamental principle that underlies many phenomena. A comprehensive understanding of this concept enables professionals to innovate and improve technologies that impact our daily lives. As we continue to explore the intricacies of wave behavior, the potential applications of wave excitation will undoubtedly expand, paving the way for advancements across multiple fields.

在物理和工程学领域，理解wave excitation（波激励）这一概念对分析各种系统至关重要。wave excitation（波激励）指的是由于外部力量或影响而在介质中产生或诱导波的过程。这种现象可以在众多应用中观察到，从机械系统到电磁场。例如，当吉他弦被拨动时，拨动动作中的能量使弦振动，导致声波的产生。这是wave excitation（波激励）的一个实际例子，其中初始动作导致一系列通过空气传播的振荡。wave excitation（波激励）的重要性不仅限于乐器；它在结构动力学和声学等工程学科中发挥着关键作用。工程师常常需要考虑结构如何响应各种类型的激励，包括地震期间的地震波或高楼大厦中的风引起的振动。通过理解wave excitation（波激励），工程师可以设计能够承受这些力量的结构，从而确保安全和耐用性。此外，wave excitation（波激励）不仅限于物理结构，也与电磁波领域相关。在电信中，例如，天线被设计用于通过wave excitation（波激励）生成和传输无线电波。支配这种激励的原理对于优化信号强度和清晰度至关重要，这对有效通信至关重要。wave excitation（波激励）适用的另一个迷人领域是海洋波浪的研究。风与水之间的相互作用产生波浪，这是自然界中wave excitation（波激励）的经典例子。理解这个过程对于预测天气模式、设计船只，甚至利用波浪能作为可再生资源至关重要。此外，在医学领域，wave excitation（波激励）的研究在超声技术中尤为重要。超声波机器利用wave excitation（波激励）通过向体内发送高频声波并分析返回的回声来创建内部器官的图像。这种非侵入性技术彻底改变了诊断，并证明了理解波行为的重要性。总之，wave excitation（波激励）这一概念是多个科学和工程领域的基础。无论是在音乐、结构完整性、电信、海洋学还是医学的背景下，wave excitation（波激励）都作为一个基本原理，支撑着许多现象。对该概念的全面理解使专业人士能够创新和改善影响我们日常生活的技术。随着我们继续探索波行为的复杂性，wave excitation（波激励）的潜在应用无疑会扩展，为多个领域的进步铺平道路。