electron oscillograph

简明释义

电子示波器

英英释义

例句

1.During the experiment, the electron oscillograph displayed unexpected results.

在实验过程中，电子振荡示波器显示了意想不到的结果。

2.In the lab, the electron oscillograph helped visualize the waveform of the electrical circuit.

在实验室中，电子振荡示波器帮助可视化电路的波形。

3.The technician calibrated the electron oscillograph for accurate readings.

技术员对电子振荡示波器进行了校准，以确保读数准确。

4.The electron oscillograph is essential for analyzing high-frequency signals.

电子振荡示波器对于分析高频信号至关重要。

5.The engineer used the electron oscillograph to measure the frequency of the signal.

工程师使用电子振荡示波器来测量信号的频率。

作文

The world of electronics and physics is filled with fascinating instruments that have transformed our understanding of waveforms and signals. One such instrument is the electron oscillograph, which plays a crucial role in visualizing electrical signals. The electron oscillograph is an advanced device that utilizes the principles of electron beams to create detailed representations of voltage changes over time. This technology has been pivotal in various fields, including telecommunications, audio engineering, and medical diagnostics.To understand the significance of the electron oscillograph, we must first explore its functionality. At its core, the electron oscillograph operates by directing a beam of electrons onto a phosphorescent screen. As the electrons strike the screen, they produce a visible trace that corresponds to the electrical signal being analyzed. This allows engineers and scientists to observe the waveform characteristics, such as amplitude, frequency, and phase shift, in real-time.Historically, the development of the electron oscillograph marked a significant advancement in electronic measurement tools. Before its invention, oscilloscopes relied on mechanical methods to depict signals, which were often limited in accuracy and speed. The introduction of the electron oscillograph revolutionized this field, providing a more precise and efficient means of capturing transient phenomena. This innovation enabled researchers to delve deeper into the complexities of electronic circuits and signal processing.In practical applications, the electron oscillograph has proven invaluable. For instance, in telecommunications, it helps engineers analyze signal integrity and troubleshoot issues related to data transmission. By visualizing the waveform, they can identify distortions or noise that may hinder communication quality. Similarly, in audio engineering, the electron oscillograph assists sound technicians in optimizing audio signals, ensuring that recordings are clear and free from unwanted artifacts.Moreover, the electron oscillograph has found its place in the medical field, particularly in the realm of electrocardiograms (ECGs). Medical professionals utilize this technology to monitor heart activity by capturing the electrical impulses that trigger each heartbeat. The ability to visualize these signals in real-time aids in diagnosing various cardiac conditions, ultimately improving patient care.Despite the emergence of digital oscilloscopes and other modern technologies, the electron oscillograph remains relevant due to its unique advantages. Its high-speed response and ability to handle high-frequency signals make it a preferred choice for certain applications. Furthermore, the fundamental principles behind the electron oscillograph continue to inform advancements in electronic measurement techniques.In conclusion, the electron oscillograph is an essential tool that has significantly impacted various scientific and engineering disciplines. Its ability to visualize electrical signals with precision has facilitated numerous breakthroughs in technology and medicine. As we continue to explore the frontiers of electronics, the legacy of the electron oscillograph will undoubtedly endure, inspiring future innovations and discoveries in the field of signal analysis.

电子和物理的世界充满了迷人的仪器，这些仪器改变了我们对波形和信号的理解。电子振荡仪就是其中一种在可视化电信号方面发挥着关键作用的仪器。电子振荡仪是一种先进的设备，利用电子束的原理创建电压随时间变化的详细表示。这项技术在电信、音频工程和医学诊断等多个领域至关重要。要理解电子振荡仪的重要性，我们首先必须探讨其功能。电子振荡仪的核心原理是将电子束引导到磷光屏上。当电子撞击屏幕时，会产生与正在分析的电信号相对应的可见痕迹。这使得工程师和科学家能够实时观察波形特征，如幅度、频率和相位偏移。从历史上看，电子振荡仪的发展标志着电子测量工具的重大进步。在它发明之前，示波器依赖机械方法来描绘信号，这往往在精确度和速度上受到限制。电子振荡仪的引入彻底革新了这一领域，提供了一种更精确高效的捕捉瞬态现象的手段。这一创新使研究人员能够更深入地探索电子电路和信号处理的复杂性。在实际应用中，电子振荡仪被证明是无价之宝。例如，在电信领域，它帮助工程师分析信号完整性并排除与数据传输相关的问题。通过可视化波形，他们可以识别可能影响通信质量的失真或噪声。同样，在音频工程中，电子振荡仪帮助声音技术人员优化音频信号，确保录音清晰且没有不必要的伪影。此外，电子振荡仪在医疗领域也找到了自己的位置，特别是在心电图（ECG）领域。医疗专业人员利用这项技术监测心脏活动，通过捕捉触发每次心跳的电冲动。实时可视化这些信号的能力有助于诊断各种心脏疾病，从而改善患者护理。尽管数字示波器和其他现代技术的出现，电子振荡仪因其独特的优势而仍然相关。其高速响应和处理高频信号的能力使其在某些应用中成为首选。此外，电子振荡仪背后的基本原理继续为电子测量技术的进步提供指导。总之，电子振荡仪是一个重要的工具，对多个科学和工程学科产生了重大影响。它以精确的方式可视化电信号的能力促进了技术和医学的众多突破。随着我们继续探索电子学的前沿，电子振荡仪的遗产无疑将持续存在，激励未来在信号分析领域的创新和发现。