wavemeter
简明释义
英[/ˈweɪvˌmiːtər/]美[/ˈweɪvˌmiːtər/]
n. [电子] 波长计;波浪表
英英释义
A wavemeter is an instrument used to measure the wavelength of electromagnetic waves, especially in the radio frequency range. | 波长计是一种用于测量电磁波波长的仪器,特别是在射频范围内。 |
单词用法
同义词
反义词
| 静止 | The ocean was in a state of stillness, with no waves in sight. | 海洋处于静止状态,视野中没有波浪。 | |
| 平静 | The weather forecast predicts calm conditions for the weekend. | 天气预报预测周末将有平静的天气。 |
例句
1.All factors concerning this type of wavemeter are thoroughly investigated from the theoretical consideratio…
且按原理及初步实验,将凡关于此种波长计各节,亦已详细研究。
2.The above results are verified by the measurement of a cavity wavemeter of the absorption type working on 3-cm wavelength.
最后通过对三厘米波段吸收式空腔波长计的测量,验证了上述计算公式的正确性。
3.The above results are verified by the measurement of a cavity wavemeter of the absorption type working on 3-cm wavelength.
最后通过对三厘米波段吸收式空腔波长计的测量,验证了上述计算公式的正确性。
4.During the experiment, the wavemeter showed unexpected fluctuations in wavelength.
在实验过程中,wavemeter显示出波长的意外波动。
5.In the lab, we calibrated the wavemeter to ensure precise readings.
在实验室,我们校准了wavemeter以确保读数的准确性。
6.Engineers rely on the wavemeter for tuning radio frequencies.
工程师依赖wavemeter来调整无线电频率。
7.The wavemeter is essential for testing the performance of optical devices.
wavemeter对于测试光学设备的性能至关重要。
8.The scientist used a wavemeter to accurately measure the frequency of the laser beam.
科学家使用wavemeter准确测量激光束的频率。
作文
In the realm of physics and engineering, the measurement of waves is crucial for various applications, ranging from telecommunications to environmental monitoring. One of the essential tools used in this field is the wavemeter, which is an instrument designed to measure the wavelength of electromagnetic waves. Understanding how a wavemeter operates can provide insights into its significance and applications in modern technology.A wavemeter typically works by analyzing the interference patterns created by waves, often utilizing a laser source. When a wave encounters an obstacle or another wave, it can create a pattern of constructive and destructive interference. By measuring these patterns, the wavemeter can accurately determine the wavelength of the wave being analyzed. This information is vital for engineers and scientists who need precise measurements for their experiments or designs.The applications of a wavemeter are vast. In telecommunications, for instance, knowing the exact wavelength of signals can help optimize transmission systems. Engineers can adjust their equipment to minimize losses and improve signal clarity when they have precise data about the wavelengths being transmitted. Similarly, in the field of optics, a wavemeter can be used to calibrate lasers, ensuring that they emit light at the desired wavelength for various applications, including medical procedures and manufacturing processes.Moreover, a wavemeter is also employed in scientific research. Researchers studying the properties of different materials often need to know how those materials interact with various wavelengths of light. By using a wavemeter, they can gather critical data that aids in the development of new technologies, such as advanced sensors or photonic devices.One of the most exciting developments in the use of wavemeters is their application in environmental monitoring. With the increasing concern over climate change and pollution, scientists are using these instruments to measure wavelengths associated with various atmospheric phenomena. For example, a wavemeter can help detect changes in the wavelengths of light that pass through the atmosphere, providing valuable data on air quality and greenhouse gas concentrations.Despite the advancements in technology, operating a wavemeter requires a solid understanding of both wave theory and the specific instrument being used. Users must be trained to interpret the data accurately and understand the limitations of their measurements. Factors such as temperature, humidity, and even the presence of other electromagnetic fields can affect the readings obtained from a wavemeter. Therefore, careful calibration and consideration of environmental conditions are essential for obtaining reliable results.In conclusion, the wavemeter is an indispensable tool in the fields of physics, engineering, and environmental science. Its ability to measure wavelengths accurately has profound implications for technology and research. As we continue to explore the complexities of waves and their interactions with matter, the role of the wavemeter will undoubtedly become even more significant, paving the way for innovations that can benefit society as a whole.
在物理和工程领域,波的测量对各种应用至关重要,从电信到环境监测。其中一种基本工具是wavemeter,这是一种用于测量电磁波波长的仪器。理解wavemeter的工作原理可以提供对其重要性和现代技术应用的深入了解。wavemeter通常通过分析波产生的干涉图案来工作,通常使用激光源。当波遇到障碍物或另一波时,可能会产生建设性和破坏性干涉的图案。通过测量这些图案,wavemeter可以准确确定被分析波的波长。这些信息对于需要精确测量的工程师和科学家至关重要,无论是进行实验还是设计。wavemeter的应用非常广泛。例如,在电信领域,了解信号的确切波长可以帮助优化传输系统。当工程师拥有关于传输波长的精确数据时,他们可以调整设备以最小化损失并提高信号清晰度。同样,在光学领域,wavemeter可用于校准激光,确保它们以所需波长发出光线,用于医疗程序和制造过程等各种应用。此外,wavemeter还被用于科学研究。研究不同材料特性的研究人员往往需要知道这些材料与各种波长的光相互作用的方式。通过使用wavemeter,他们可以收集关键数据,有助于新技术的发展,例如先进的传感器或光子设备。在wavemeter应用中,一个令人兴奋的发展是它在环境监测中的应用。随着对气候变化和污染的日益关注,科学家们正在利用这些仪器测量与各种大气现象相关的波长。例如,wavemeter可以帮助检测穿过大气的光波长的变化,提供有关空气质量和温室气体浓度的宝贵数据。尽管技术不断进步,但操作wavemeter仍需要对波理论和所使用的特定仪器有扎实的理解。用户必须经过培训,以准确解释数据并理解测量的局限性。温度、湿度甚至其他电磁场的存在等因素都可能影响从wavemeter获得的读数。因此,仔细校准和考虑环境条件对于获得可靠结果至关重要。总之,wavemeter是物理、工程和环境科学领域不可或缺的工具。它准确测量波长的能力对技术和研究具有深远的影响。随着我们继续探索波及其与物质相互作用的复杂性,wavemeter的作用无疑会变得更加重要,为能够造福整个社会的创新铺平道路。
