resonators

简明释义

英[ˈrɛzəneɪtəz]美[ˈrɛzəˌneɪtərz]

n. [电子]谐振器；[声]共鸣器（resonator 的复数）

英英释义

单词用法

同义词

反义词

例句

1.Using ray-matrix method we investigated the resonators containing two kinds of apertures.

用光线矩阵方法研究了两类带有光阑的谐振腔。

2.Quartz crystal resonators are devices that supply standard time base.

石英晶体谐振器是一种提供基准时基的器件。

3.An optical header serial-to-parallel conversion technology using microring resonators is reported.

提出了一种基于微环谐振器的光分组头串并转换方法。

4.The resulting diplexers require fewer resonators than conventional E-plane diplexers to achieve comparable performance.

这种双工器用比传统的E面双工器少的谐振腔而到达相同的性能。

5.Applying the new techniques to the resonators of low frequency filters, satisfied results are being obtained.

将该工艺应用到低频滤波器用谐振子中，同样得到了满意的结果。

6.The beam characteristics with positive and negative branch unstable resonators were compared for end-and edge-pumped lasers.

在端面抽运和边缘抽运时，比较了正支和负支非稳腔的输出光束特性。

7.The mode characteristics of two hexagonal resonators are also analyzed, and the ideas of filter design are given.

同时分析了两个六角形谐振器的模式特征，给出了其设计滤波器的思路。

8.The engineer designed a new type of resonators 谐振器 to improve the performance of the sound system.

工程师设计了一种新型的resonators 谐振器以提高音响系统的性能。

9.In musical instruments, resonators 谐振器 enhance the sound quality and volume.

在乐器中，resonators 谐振器增强了音质和音量。

10.Researchers are studying how different shapes of resonators 谐振器 affect their efficiency.

研究人员正在研究不同形状的resonators 谐振器如何影响其效率。

11.The resonators 谐振器 in the microwave oven help to evenly distribute heat.

微波炉中的resonators 谐振器有助于均匀分配热量。

12.Acoustic resonators 谐振器 are crucial for tuning the sound of a guitar.

声学resonators 谐振器对于调音吉他的声音至关重要。

作文

In the world of physics and engineering, the term resonators refers to devices or systems that exhibit resonance. Resonance is a phenomenon that occurs when an object vibrates at its natural frequency due to an external force. This concept is not only fascinating but also has practical applications in various fields, including music, telecommunications, and even medicine. Understanding how resonators work can provide insight into both the theoretical and practical aspects of wave dynamics. One of the most common examples of resonators is found in musical instruments. For instance, a guitar string vibrates when plucked, and the body of the guitar acts as a resonator, amplifying the sound produced by the string. The shape and material of the guitar body determine the quality and richness of the sound. Similarly, in wind instruments, the air column inside the instrument serves as a resonator, enhancing specific frequencies to create a pleasing sound. This relationship between the vibrating source and the resonator is crucial for musicians and instrument makers alike, as it directly impacts the tonal quality of the music produced. Beyond music, resonators play a critical role in telecommunications. In radio transmitters and receivers, resonators are used to select specific frequencies from a range of signals. By tuning the resonator to a particular frequency, engineers can filter out unwanted signals and enhance the clarity of the communication. This principle is also applied in microwave technology, where resonators are essential for the functioning of devices such as oscillators and filters. The ability to manipulate and control frequencies through resonators has revolutionized modern communication, making it faster and more efficient. In the field of medicine, resonators are utilized in various diagnostic tools. For example, Magnetic Resonance Imaging (MRI) machines use the principles of resonance to create detailed images of the human body. The machine generates a magnetic field that interacts with the hydrogen atoms in the body, causing them to resonate. This resonance produces signals that are then converted into images, allowing doctors to diagnose conditions with remarkable accuracy. The application of resonators in medical technology underscores their importance in advancing healthcare and improving patient outcomes. Despite their diverse applications, the underlying principles governing resonators remain consistent. They rely on the interaction between energy and matter, where energy input leads to resonant behavior in the system. This understanding opens up new avenues for research and innovation, as scientists and engineers continue to explore the potential of resonators in emerging technologies. In conclusion, the concept of resonators is integral to various disciplines, from music to telecommunications and medicine. Their ability to enhance and manipulate sound and signals has profound implications for both scientific research and everyday life. As we continue to study and harness the power of resonators, we unlock new possibilities for innovation and creativity in our increasingly complex world.

在物理和工程学的世界中，术语resonators指的是表现出共振的设备或系统。共振是一种现象，当一个物体由于外力的作用以其自然频率振动时，就会发生这种现象。这个概念不仅引人入胜，而且在音乐、电信甚至医学等多个领域具有实际应用。理解resonators的工作原理可以提供对波动态理论和实际方面的洞察。 最常见的resonators示例之一可以在乐器中找到。例如，吉他弦在拨动时振动，而吉他的琴身作为一个resonator，放大了弦产生的声音。吉他琴身的形状和材料决定了声音的质量和丰富性。同样，在吹奏乐器中，乐器内部的空气柱充当resonator，增强特定频率以创造悦耳的声音。这种振动源与resonator之间的关系对于音乐家和乐器制造者来说至关重要，因为它直接影响到所产生音乐的音色质量。 除了音乐，resonators在电信中也发挥着关键作用。在无线电发射器和接收器中，resonators用于从一系列信号中选择特定频率。通过将resonator调整到特定频率，工程师可以过滤掉不需要的信号并增强通信的清晰度。这个原理也应用于微波技术，在那里，resonators对于振荡器和过滤器等设备的功能至关重要。通过resonators操控和控制频率的能力彻底改变了现代通信，使其更加快速和高效。 在医学领域，resonators被应用于各种诊断工具。例如，磁共振成像（MRI）机利用共振原理创建人体的详细图像。该机器生成一个磁场，与身体中的氢原子相互作用，使其产生共振。这种共振产生的信号随后被转换为图像，使医生能够以惊人的准确度诊断疾病。resonators在医疗技术中的应用突显了它们在推进医疗保健和改善患者结果方面的重要性。 尽管它们的应用多种多样，但支配resonators的基本原理仍然是一致的。它们依赖于能量与物质之间的相互作用，其中能量输入导致系统中的共振行为。这种理解为研究和创新开辟了新的途径，因为科学家和工程师继续探索resonators在新兴技术中的潜力。 总之，resonators的概念在多个学科中都是不可或缺的，从音乐到电信和医学。它们增强和操控声音和信号的能力对科学研究和日常生活都有深远的影响。随着我们继续研究和利用resonators的力量，我们为创新和创造力在日益复杂的世界中开启了新的可能性。