resonance region
简明释义
共振范围
英英释义
例句
1.In quantum mechanics, the energy levels of electrons can be described within the resonance region 共振区, where they exhibit enhanced probabilities of being found.
在量子力学中,电子的能级可以在共振区 resonance region中描述,在这里它们显示出被发现的概率增强。
2.Engineers often analyze the resonance region 共振区 of a structure to prevent potential failure due to vibrations.
工程师通常分析结构的共振区 resonance region以防止因振动而导致的潜在故障。
3.The resonance region 共振区 of a musical instrument determines its unique sound quality.
乐器的共振区 resonance region决定了其独特的音质。
4.The resonance region 共振区 in acoustics refers to frequencies at which a system naturally oscillates with higher amplitude.
声学中的共振区 resonance region是指系统自然以更高幅度振荡的频率。
5.In optics, the resonance region 共振区 can affect how light is absorbed or emitted by materials.
在光学中,共振区 resonance region可以影响材料如何吸收或发射光。
作文
In the field of physics and engineering, the term resonance region refers to a specific range of frequencies at which a system exhibits a significant increase in amplitude due to resonance. This phenomenon occurs when the frequency of an external force matches the natural frequency of the system, causing it to oscillate with greater intensity. Understanding the resonance region is crucial for various applications, from designing musical instruments to developing bridges and buildings that can withstand seismic activities.One of the most common examples of the resonance region can be found in musical instruments. For instance, when a guitar string is plucked, it vibrates at its natural frequency, producing sound. The resonance region in this context is the range of frequencies that enhance the sound produced by the string. Musicians often tune their instruments to ensure that they resonate well within this region, allowing for a richer and more vibrant sound.In engineering, understanding the resonance region is vital for ensuring the structural integrity of buildings and bridges. Engineers must consider the natural frequencies of these structures and how they align with potential external forces, such as wind or earthquakes. If a building is subjected to vibrations that fall within its resonance region, it could lead to catastrophic failures. Therefore, engineers often conduct detailed analyses to identify these frequencies and design structures that avoid resonance.Another fascinating application of the resonance region is in the field of medicine, particularly in magnetic resonance imaging (MRI). In MRI machines, the resonance region relates to the specific frequencies of radio waves that can excite hydrogen atoms in the body. By manipulating these frequencies, doctors can obtain detailed images of internal organs and tissues. This technology has revolutionized diagnostics, allowing for early detection of diseases and improved patient outcomes.The concept of the resonance region also extends to other fields, such as acoustics and electronics. In acoustics, sound engineers utilize the resonance region to optimize sound quality in concert halls and recording studios. By understanding how sound waves interact with different materials, they can create spaces that enhance the listening experience.In electronics, the resonance region plays a critical role in the design of circuits and filters. Engineers must carefully select components that operate within the desired resonance region to ensure optimal performance. This is particularly important in communication systems, where signal clarity and strength are paramount.In conclusion, the resonance region is a fundamental concept that spans multiple disciplines, including music, engineering, medicine, acoustics, and electronics. Its significance lies in the profound effects it has on the behavior of systems under specific conditions. By grasping the intricacies of the resonance region, professionals can innovate and improve technologies, ultimately enhancing our daily lives. As we continue to explore this fascinating area, we unlock new possibilities and advancements that can benefit society as a whole.
在物理和工程领域,术语共振区指的是一个特定的频率范围,在该范围内,系统由于共振而表现出显著的振幅增加。这种现象发生在外部力量的频率与系统的自然频率相匹配时,导致其以更大的强度振荡。理解共振区对各种应用至关重要,从设计乐器到开发能够抵御地震活动的桥梁和建筑。共振区的一个常见例子可以在乐器中找到。例如,当吉他弦被拨动时,它以其自然频率振动,产生声音。在这种情况下,共振区是增强弦所产生的声音的频率范围。音乐家通常会调音,以确保他们的乐器在这一区域内良好共振,从而产生更丰富、更生动的声音。在工程中,理解共振区对确保建筑和桥梁的结构完整性至关重要。工程师必须考虑这些结构的自然频率以及它们如何与潜在的外部力量(如风或地震)对齐。如果一座建筑遭受落入其共振区的振动,可能会导致灾难性故障。因此,工程师通常会进行详细分析,以识别这些频率并设计避免共振的结构。共振区的另一个迷人应用是在医学领域,特别是在磁共振成像(MRI)中。在MRI机器中,共振区与可以激发体内氢原子的无线电波的特定频率相关。通过操纵这些频率,医生可以获得内部器官和组织的详细图像。这项技术彻底改变了诊断,允许早期发现疾病并改善患者结果。共振区的概念还扩展到其他领域,如声学和电子学。在声学中,声音工程师利用共振区来优化音乐厅和录音室的音质。通过理解声波如何与不同材料相互作用,他们可以创建增强听觉体验的空间。在电子学中,共振区在电路和滤波器的设计中起着关键作用。工程师必须仔细选择在所需的共振区内运行的组件,以确保最佳性能。这在通信系统中尤为重要,其中信号的清晰度和强度至关重要。总之,共振区是一个基本概念,跨越多个学科,包括音乐、工程、医学、声学和电子学。它的重要性在于它对系统在特定条件下行为的深远影响。通过掌握共振区的复杂性,专业人士可以创新和改进技术,从而最终提升我们的日常生活。随着我们继续探索这一迷人领域,我们解锁了新的可能性和进步,这些进步可以惠及整个社会。
