electromagnetic oscillograph

简明释义

电磁式示波器

英英释义

例句

1.The technician calibrated the electromagnetic oscillograph before conducting the experiment.

技术人员在进行实验之前对电磁振荡仪进行了校准。

2.Using an electromagnetic oscillograph helps in diagnosing faults in electrical systems.

使用电磁振荡仪有助于诊断电气系统中的故障。

3.In the lab, the electromagnetic oscillograph provided precise measurements of signal waveforms.

在实验室中，电磁振荡仪提供了信号波形的精确测量。

4.By connecting the electromagnetic oscillograph to the power line, we could visualize the electrical noise present.

通过将电磁振荡仪连接到电力线，我们可以可视化存在的电噪声。

5.The engineer used an electromagnetic oscillograph to analyze the frequency response of the circuit.

工程师使用电磁振荡仪来分析电路的频率响应。

作文

The invention of the electromagnetic oscillograph has significantly transformed the field of electrical engineering and physics. This sophisticated device is designed to measure and visualize electrical signals over time, enabling engineers and scientists to analyze the behavior of various systems. The electromagnetic oscillograph operates by converting electrical signals into visual representations, typically on a screen or paper, allowing for detailed examination of waveforms and frequencies. Historically, the development of oscillographs can be traced back to the early 20th century when researchers sought ways to better understand electrical phenomena. The electromagnetic oscillograph emerged as a critical tool during this period, providing insights that were previously unattainable. With its ability to capture rapid changes in electrical signals, it became indispensable in laboratories and industries alike. One of the key advantages of the electromagnetic oscillograph is its precision. It can accurately depict the amplitude, frequency, and phase of electrical signals, making it invaluable for diagnosing issues in electronic circuits. For example, engineers can use this device to troubleshoot malfunctioning equipment by observing irregularities in the waveform. By analyzing the data presented by the electromagnetic oscillograph, they can pinpoint the exact source of the problem, whether it be a faulty component or an unexpected interference. Moreover, the electromagnetic oscillograph plays a crucial role in research and development. In academic settings, physicists utilize it to study the properties of electromagnetic waves and their interactions with different materials. This research is essential for advancing technologies such as telecommunications, where understanding signal transmission is key. The ability to visualize complex waveforms allows scientists to test theories and refine models, ultimately leading to innovations that benefit society. In addition to its applications in engineering and research, the electromagnetic oscillograph is also used in educational environments. Students studying electronics and physics can gain hands-on experience with this device, helping them grasp fundamental concepts related to electrical signals. By observing how different components affect the waveform, learners develop a deeper understanding of circuit behavior and signal processing. As technology continues to evolve, the electromagnetic oscillograph has undergone significant advancements. Modern versions are equipped with digital displays and advanced software, allowing for real-time analysis and data storage. These enhancements have made the device more user-friendly and versatile, catering to a wider range of applications. For instance, digital oscillographs can now interface with computers, enabling users to manipulate data and generate reports with ease. In conclusion, the electromagnetic oscillograph is a vital instrument in the fields of electrical engineering and physics. Its ability to measure and visualize electrical signals has revolutionized the way we understand and interact with electrical systems. From troubleshooting electronic devices to conducting groundbreaking research, the electromagnetic oscillograph remains an essential tool that continues to evolve alongside technological advancements. As we look to the future, it is clear that this remarkable device will play a pivotal role in shaping the next generation of innovations in science and engineering.

电磁振荡仪的发明显著改变了电气工程和物理学领域。这种复杂的设备旨在测量和可视化电信号随时间的变化，使工程师和科学家能够分析各种系统的行为。电磁振荡仪通过将电信号转换为视觉表现，通常是在屏幕或纸张上，从而允许对波形和频率进行详细检查。历史上，振荡仪的发展可以追溯到20世纪初，当时研究人员寻求更好地理解电现象。电磁振荡仪在这一时期成为了一种关键工具，提供了以前无法获得的见解。凭借其捕捉电信号快速变化的能力，它在实验室和工业中变得不可或缺。电磁振荡仪的一个主要优点是其精确性。它可以准确描绘电信号的幅度、频率和相位，使其在诊断电子电路问题时具有重要价值。例如，工程师可以使用该设备来排查故障设备的问题，通过观察波形中的不规律性。通过分析电磁振荡仪提供的数据，他们可以准确找出问题的根源，无论是故障组件还是意外干扰。此外，电磁振荡仪在研究和开发中也发挥着至关重要的作用。在学术环境中，物理学家利用它研究电磁波的特性及其与不同材料的相互作用。这项研究对于推进电信等技术至关重要，因为理解信号传输是关键。可视化复杂波形的能力使科学家能够测试理论并完善模型，最终导致有益于社会的创新。除了在工程和研究中的应用，电磁振荡仪还用于教育环境。学习电子学和物理学的学生可以通过使用该设备获得实践经验，帮助他们掌握与电信号相关的基本概念。通过观察不同组件如何影响波形，学习者对电路行为和信号处理的发展有更深入的理解。随着技术的不断发展，电磁振荡仪也经历了显著的进步。现代版本配备了数字显示器和先进的软件，允许实时分析和数据存储。这些增强使设备更易于使用和多功能，适应更广泛的应用。例如，数字振荡仪现在可以与计算机接口，使用户能够轻松操作数据并生成报告。总之，电磁振荡仪是电气工程和物理学领域的重要仪器。其测量和可视化电信号的能力革命性地改变了我们理解和与电气系统互动的方式。从故障排除电子设备到进行开创性研究，电磁振荡仪仍然是一个至关重要的工具，继续随着技术进步而发展。展望未来，很明显，这种非凡的设备将在塑造下一代科学和工程创新中发挥关键作用。