fundamental oscillation

简明释义

基波振荡

英英释义

例句

1.Engineers must consider the fundamental oscillation of materials when designing structures to ensure stability.

工程师在设计结构时必须考虑材料的基本振荡以确保稳定性。

2.The study of wave mechanics often begins with the concept of fundamental oscillation, which refers to the basic frequency at which a system vibrates.

波动力学的研究通常从基本振荡的概念开始，这指的是一个系统振动的基本频率。

3.In quantum mechanics, the fundamental oscillation of particles can define their energy levels.

在量子力学中，粒子的基本振荡可以定义它们的能级。

4.In musical acoustics, the fundamental oscillation of a string determines the pitch of the note produced.

在音乐声学中，弦的基本振荡决定了产生音符的音高。

5.The fundamental oscillation of a pendulum is crucial for accurate timekeeping in clocks.

摆的基本振荡对钟表的准确计时至关重要。

作文

In the realm of physics, the concept of fundamental oscillation (基本振荡) plays a crucial role in understanding various phenomena. At its core, fundamental oscillation refers to the basic mode of oscillation in a system, which is characterized by a specific frequency and amplitude. This concept is not only pivotal in theoretical physics but also has practical applications across different fields such as engineering, music, and even medicine.To illustrate the importance of fundamental oscillation (基本振荡), let’s consider a simple example: a guitar string. When a guitar string is plucked, it vibrates and produces sound. The lowest frequency at which the string vibrates is known as its fundamental frequency. This frequency corresponds to the fundamental oscillation (基本振荡) of the string. The sound produced is rich and full because it includes not just the fundamental frequency but also higher harmonics, which are integer multiples of this frequency. Thus, the fundamental oscillation (基本振荡) sets the foundation for the sound quality of the instrument.In engineering, particularly in the design of structures like bridges and buildings, understanding the fundamental oscillation (基本振荡) of materials is essential. Every structure has a natural frequency at which it tends to oscillate. If external forces, such as wind or earthquakes, match this frequency, resonance can occur, potentially leading to catastrophic failure. Therefore, engineers must calculate the fundamental oscillation (基本振荡) of the structures they design to ensure safety and stability.Moreover, in the field of medicine, the concept of fundamental oscillation (基本振荡) can be observed in various biological systems. For instance, the human heart exhibits oscillatory behavior as it beats. The fundamental oscillation (基本振荡) of the heart is crucial for maintaining a steady rhythm, which is vital for effective blood circulation. Any irregularities in this oscillation can lead to health issues, highlighting the significance of understanding these patterns in medical diagnostics.In summary, the notion of fundamental oscillation (基本振荡) extends far beyond mere theoretical implications; it has tangible effects on our daily lives and the functioning of various systems. From musical instruments to architectural designs and biological rhythms, recognizing and analyzing fundamental oscillation (基本振荡) allows us to innovate and improve across multiple disciplines. As we continue to explore the intricate details of oscillatory behavior, the relevance of fundamental oscillation (基本振荡) will undoubtedly remain a cornerstone in both scientific inquiry and practical applications.

在物理学领域，基本振荡的概念在理解各种现象中起着至关重要的作用。基本振荡指的是系统中的基本振荡模式，其特征是特定的频率和振幅。这个概念不仅在理论物理中至关重要，而且在工程、音乐甚至医学等不同领域也有实际应用。为了说明基本振荡的重要性，我们来看一个简单的例子：吉他弦。当吉他弦被拨动时，它会振动并产生声音。弦振动的最低频率被称为其基本频率。这一频率对应于弦的基本振荡。产生的声音丰富而饱满，因为它不仅包括基本频率，还包括更高的谐波，这些谐波是该频率的整数倍。因此，基本振荡为乐器的音质奠定了基础。在工程学中，特别是在桥梁和建筑物的设计中，理解材料的基本振荡至关重要。每个结构都有一个自然频率，在此频率下它倾向于振荡。如果外部力量（例如风或地震）与此频率相匹配，就可能发生共振，导致灾难性的失败。因此，工程师必须计算他们设计的结构的基本振荡以确保安全和稳定。此外，在医学领域，基本振荡的概念可以在各种生物系统中观察到。例如，人类心脏在跳动时表现出振荡行为。心脏的基本振荡对于维持稳定的节律至关重要，这对有效的血液循环至关重要。这种振荡中的任何不规则性都可能导致健康问题，突显了在医学诊断中理解这些模式的重要性。总之，基本振荡的概念远不止于理论意义；它对我们的日常生活和各种系统的功能有着切实的影响。从乐器到建筑设计，再到生物节律，认识和分析基本振荡使我们能够在多个学科中进行创新和改进。随着我们继续探索振荡行为的复杂细节，基本振荡的相关性无疑将继续成为科学研究和实际应用的基石。