dynamic resonance

简明释义

动态谐振

英英释义

例句

1.The scientist studied how dynamic resonance 动态共鸣 affects the behavior of molecules in a solution.

科学家研究了动态共鸣 动态共鸣 如何影响溶液中分子的行为。

2.During the presentation, the speaker highlighted the importance of dynamic resonance 动态共鸣 in effective communication.

在演讲中，发言者强调了动态共鸣 动态共鸣 在有效沟通中的重要性。

3.The dancers moved in sync, creating a dynamic resonance 动态共鸣 that captivated the audience.

舞者们同步移动，创造出一种吸引观众的动态共鸣 动态共鸣。

4.In architecture, dynamic resonance 动态共鸣 can enhance the acoustic properties of a concert hall.

在建筑中，动态共鸣 动态共鸣 可以增强音乐厅的声学特性。

5.The orchestra achieved a beautiful sound through the dynamic resonance 动态共鸣 of the instruments.

乐团通过乐器的动态共鸣 动态共鸣 达成了美妙的声音。

作文

In the realm of physics and engineering, the concept of dynamic resonance plays a pivotal role in understanding how systems respond to external forces. Dynamic resonance refers to the phenomenon where a system oscillates with greater amplitude at specific frequencies known as the system's natural frequencies. This behavior can be observed in various contexts, from musical instruments to architectural structures. Understanding dynamic resonance is crucial for designing systems that are both efficient and safe.One of the most common examples of dynamic resonance can be found in music. When a musician plays a note on a guitar, the strings vibrate at certain frequencies, producing sound waves. If the frequency of the played note matches the natural frequency of the guitar body, the instrument will resonate, amplifying the sound. This principle is not only limited to musical instruments; it applies to any system capable of oscillation. For instance, in buildings, dynamic resonance can lead to catastrophic failures if the structure resonates with wind or seismic activity.Another significant application of dynamic resonance is in the field of mechanical engineering. Engineers must carefully consider the natural frequencies of components when designing machinery. If an engine operates at a speed that coincides with the natural frequency of its parts, it may result in excessive vibrations, leading to wear and tear or even mechanical failure. Therefore, understanding dynamic resonance allows engineers to mitigate risks by designing systems that avoid resonant frequencies.Moreover, dynamic resonance has implications in the field of electronics. In circuits, components such as inductors and capacitors can create resonant circuits that amplify signals at certain frequencies. This principle is widely used in radio technology, where tuning into a specific frequency allows the reception of desired signals while filtering out noise. Thus, the understanding of dynamic resonance is essential for developing effective communication devices.The study of dynamic resonance also extends to biology. In biological systems, resonance phenomena can affect the behavior of cells and tissues. For example, certain frequencies of sound have been shown to influence cellular processes, potentially leading to advancements in medical therapies. This intersection of physics and biology highlights the importance of dynamic resonance in understanding complex systems.In conclusion, dynamic resonance is a multifaceted concept that spans various fields, including music, engineering, electronics, and biology. Its ability to describe how systems respond to specific frequencies is essential for innovation and safety. By grasping the principles of dynamic resonance, professionals can design better instruments, safer buildings, more efficient machines, and even advanced medical treatments. As we continue to explore the intricacies of this phenomenon, we unlock new potentials across disciplines, making dynamic resonance a crucial area of study in both theoretical and practical applications.

在物理和工程领域，动态共鸣的概念在理解系统如何响应外部力量方面起着关键作用。动态共鸣指的是一种现象，其中系统在特定频率下以更大的振幅振荡，这些频率被称为系统的自然频率。这种行为可以在各种背景中观察到，从乐器到建筑结构。理解动态共鸣对于设计高效且安全的系统至关重要。一个最常见的动态共鸣例子可以在音乐中找到。当音乐家在吉他上演奏一个音符时，弦会以某些频率振动，产生声波。如果演奏的音符的频率与吉他主体的自然频率相匹配，乐器将共鸣，从而放大声音。这一原理不仅限于乐器；它适用于任何能够振荡的系统。例如，在建筑中，动态共鸣可能导致灾难性故障，如果结构与风或地震活动产生共鸣。动态共鸣的另一个重要应用是在机械工程领域。工程师在设计机械时必须仔细考虑组件的自然频率。如果发动机以与其部件的自然频率相吻合的速度运行，可能会导致过度振动，导致磨损或甚至机械故障。因此，理解动态共鸣使工程师能够通过设计避免共振频率来降低风险。此外，动态共鸣在电子学领域也具有重要意义。在电路中，电感器和电容器等组件可以创建谐振电路，在特定频率下放大信号。这一原理广泛应用于无线电技术，通过调谐到特定频率，可以接收所需的信号，同时过滤掉噪声。因此，理解动态共鸣对于开发有效的通信设备至关重要。动态共鸣的研究还扩展到生物学。在生物系统中，共鸣现象可以影响细胞和组织的行为。例如，某些频率的声音已被证明能够影响细胞过程，可能导致医学治疗的进步。这一物理学与生物学的交集凸显了理解复杂系统中动态共鸣的重要性。总之，动态共鸣是一个多方面的概念，跨越音乐、工程、电子学和生物学等多个领域。它描述系统如何响应特定频率的能力对于创新和安全至关重要。通过掌握动态共鸣的原理，专业人士可以设计更好的乐器、更安全的建筑、更高效的机器，甚至更先进的医疗治疗。随着我们继续探索这一现象的复杂性，我们解锁了各学科的新潜力，使动态共鸣成为理论和实践应用中至关重要的研究领域。