resonance oscillations

简明释义

谐振振荡

英英释义

例句

1.The researchers used a laser to measure resonance oscillations in the atomic structure, which are 共振振荡原子结构中的振荡。

研究人员使用激光测量原子结构中的共振振荡。

2.Engineers must consider resonance oscillations in their designs to prevent 共振振荡 that could lead to structural failure.

工程师在设计时必须考虑共振振荡，以防止可能导致结构失效的振荡。

3.The scientist studied the resonance oscillations of the material under different temperatures, which are 共振振荡影响材料性能。

科学家研究了材料在不同温度下的共振振荡，这些振荡影响材料性能。

4.The bridge collapsed due to unexpected resonance oscillations, which are 共振振荡 caused by wind.

由于意外的共振振荡，桥梁倒塌，这些振荡是由风引起的。

5.In music, resonance oscillations create rich tones that enhance the sound, which are 共振振荡产生丰富的音调。

在音乐中，共振振荡创造出丰富的音调，增强了声音。

作文

Resonance is a phenomenon that occurs when an object or system is driven at its natural frequency, resulting in a significant increase in amplitude. One of the most fascinating aspects of resonance is the concept of resonance oscillations (共振振荡), which refers to the oscillatory motions that arise when a system experiences resonance. These oscillations can be observed in various fields such as physics, engineering, and even music.To understand resonance oscillations (共振振荡), we must first consider the principles of oscillation. An oscillation is a repetitive variation, typically in time, of some measure about a central value. It can be seen in systems like pendulums, springs, and electrical circuits. When these systems are disturbed from their equilibrium position, they tend to return to it, often overshooting and creating a back-and-forth motion. This motion is what we call oscillation.Now, when we introduce the idea of resonance, things become even more interesting. Resonance occurs when the frequency of external forces matches the natural frequency of the system. For example, if you push a swing at just the right moments, you will make it go higher and higher; this is a simple demonstration of resonance. In this case, the swing's motion is characterized by resonance oscillations (共振振荡), where the amplitude of the oscillation increases significantly.In engineering, resonance oscillations (共振振荡) are critical considerations in the design of structures and mechanical systems. Engineers must ensure that buildings and bridges can withstand the forces generated by resonance, particularly during events like earthquakes. If the natural frequency of a structure coincides with the frequency of ground vibrations, the result can be catastrophic, leading to excessive oscillations and potential structural failure. Therefore, understanding resonance oscillations (共振振荡) is essential for creating safe and durable designs.Moreover, resonance is not limited to physical systems. In the realm of music, resonance oscillations (共振振荡) play a vital role in sound production. Musical instruments, such as guitars and violins, rely on resonance to amplify sound. The body of the instrument resonates at specific frequencies, enhancing the sound waves produced by the strings. This interaction creates rich tones and harmonics that are pleasing to the ear. Musicians often exploit resonance oscillations (共振振荡) to create unique sounds and effects, demonstrating how this phenomenon transcends mere physics and enters the realm of art.Furthermore, the study of resonance oscillations (共振振荡) has applications in various scientific fields, including medicine. For instance, Magnetic Resonance Imaging (MRI) utilizes the principles of resonance to produce detailed images of the inside of the human body. By applying a magnetic field and radio waves, MRI machines cause hydrogen atoms in the body to resonate, allowing for the visualization of tissues and organs. This application highlights the importance of resonance oscillations (共振振荡) beyond traditional physics, impacting real-world scenarios and improving healthcare.In conclusion, resonance oscillations (共振振荡) are a captivating aspect of the broader phenomenon of resonance. Whether in engineering, music, or medicine, understanding this concept enables us to harness its power effectively. From designing resilient structures to creating beautiful music and advancing medical imaging technology, resonance oscillations (共振振荡) demonstrate the interconnectedness of science and art. As we continue to explore and apply the principles of resonance, we unlock new possibilities and deepen our understanding of the world around us.

共振是一个现象，当物体或系统以其自然频率被驱动时，会导致幅度显著增加。共振的一个最迷人的方面是“resonance oscillations（共振振荡）”的概念，它指的是当系统经历共振时产生的振荡运动。这些振荡可以在物理、工程甚至音乐等多个领域中观察到。要理解resonance oscillations（共振振荡），我们必须首先考虑振荡的原理。振荡是指某个量围绕中心值重复变化的过程，通常随着时间的推移而变化。它可以在摆、弹簧和电路等系统中看到。当这些系统从其平衡位置被扰动时，它们倾向于返回，通常会超出目标并产生前后运动。这种运动就是我们所称的振荡。现在，当我们引入共振的概念时，事情变得更加有趣。共振发生在外部力量的频率与系统的自然频率相匹配时。例如，如果你在正确的时刻推秋千，你会让它越来越高；这是共振的简单演示。在这种情况下，秋千的运动特征是resonance oscillations（共振振荡），振荡的幅度显著增加。在工程学中，resonance oscillations（共振振荡）是结构和机械系统设计中的关键考虑因素。工程师必须确保建筑物和桥梁能够承受共振产生的力量，特别是在地震等事件期间。如果结构的自然频率恰好与地面振动的频率重合，结果可能是灾难性的，导致过度振荡和潜在的结构失效。因此，理解resonance oscillations（共振振荡）对于创建安全耐用的设计至关重要。此外，共振不仅限于物理系统。在音乐领域，resonance oscillations（共振振荡）在声音产生中发挥着重要作用。乐器，如吉他和小提琴，依靠共振来放大声音。乐器的主体在特定频率下共振，增强了弦产生的声波。这种相互作用创造了丰富的音调和谐波，令人耳悦。音乐家们常常利用resonance oscillations（共振振荡）来创造独特的声音和效果，展示了这一现象如何超越单纯的物理学，进入艺术的领域。此外，resonance oscillations（共振振荡）的研究在多个科学领域中也有应用，包括医学。例如，磁共振成像（MRI）利用共振的原理生成人体内部的详细图像。通过施加磁场和射频波，MRI机器使身体中的氢原子共振，从而可视化组织和器官。这一应用突显了resonance oscillations（共振振荡）在传统物理之外的重要性，影响现实世界的场景并改善医疗保健。总之，resonance oscillations（共振振荡）是更广泛的共振现象中一个引人入胜的方面。无论是在工程、音乐还是医学中，理解这一概念使我们能够有效地利用其力量。从设计耐用的结构到创造美妙的音乐，再到推动医学成像技术的发展，resonance oscillations（共振振荡）展示了科学与艺术的相互关联。随着我们继续探索和应用共振原理，我们解锁了新可能性，并加深了对周围世界的理解。