oscillographic impedancemeter

简明释义

示波阻抗计

英英释义

例句

1.In our lab, we rely on the oscillographic impedancemeter for testing high-frequency signals.

在我们的实验室中，我们依赖振荡图阻抗测量仪测试高频信号。

2.The oscillographic impedancemeter provides a visual representation of the impedance over time.

该振荡图阻抗测量仪提供了阻抗随时间变化的可视化表示。

3.Using the oscillographic impedancemeter, we were able to identify the resonance frequency of the system.

通过使用振荡图阻抗测量仪，我们能够识别系统的共振频率。

4.The engineer used an oscillographic impedancemeter to measure the impedance of the circuit accurately.

工程师使用振荡图阻抗测量仪准确测量电路的阻抗。

5.The technician calibrated the oscillographic impedancemeter before conducting the experiment.

技术员在进行实验之前对振荡图阻抗测量仪进行了校准。

作文

The field of electrical engineering has seen numerous advancements over the years, particularly in the measurement and analysis of electrical properties. One such advancement is the development of the oscillographic impedancemeter (振荡示波阻抗计), a sophisticated device used to measure the impedance of electrical circuits. Understanding how this instrument works and its significance in various applications can greatly enhance our comprehension of electrical systems.An oscillographic impedancemeter operates by applying an alternating current (AC) signal to a circuit and measuring the resulting voltage and current. By analyzing these parameters, it calculates the impedance, which is a crucial factor in determining how electrical energy is transferred through a circuit. Impedance not only includes resistance but also accounts for reactance, which arises from capacitors and inductors in the circuit. This duality makes impedance a more comprehensive measure than simple resistance alone.The importance of the oscillographic impedancemeter cannot be overstated. In modern electronics, accurate impedance measurements are essential for designing efficient circuits. For example, in radio frequency (RF) applications, mismatched impedance can lead to signal loss and degraded performance. Engineers use the oscillographic impedancemeter to ensure that components are properly matched, thus optimizing the overall functionality of the system.Moreover, the oscillographic impedancemeter plays a vital role in research and development. Scientists and engineers often need to analyze the behavior of materials and components under various conditions. By utilizing this device, they can obtain precise measurements that inform their understanding of material properties, leading to innovations in technology. For instance, the study of superconductors and their impedance characteristics can pave the way for breakthroughs in energy transmission and storage.In addition to its applications in engineering and research, the oscillographic impedancemeter is also valuable in educational settings. Students studying electrical engineering can benefit from hands-on experience with this instrument, gaining insights into the practical aspects of impedance measurement. Learning how to operate the oscillographic impedancemeter fosters a deeper understanding of theoretical concepts, bridging the gap between theory and practice.As technology continues to evolve, the oscillographic impedancemeter is likely to undergo further enhancements. The integration of digital technology and advanced algorithms may lead to more accurate and efficient measurements. Additionally, the miniaturization of devices could make oscillographic impedancemeters more accessible for various applications, from industrial settings to personal projects.In conclusion, the oscillographic impedancemeter (振荡示波阻抗计) is an indispensable tool in the realm of electrical engineering. Its ability to measure impedance accurately opens up a world of possibilities for engineers, researchers, and students alike. As we continue to explore the intricacies of electrical systems, the significance of this device will only grow, driving innovation and enhancing our understanding of the electrical phenomena that govern our technological landscape.

电气工程领域多年来经历了无数进步，特别是在电气特性的测量和分析方面。其中一个重要的进展是开发了振荡示波阻抗计，这是一种用于测量电路阻抗的复杂设备。理解该仪器的工作原理及其在各种应用中的重要性，可以大大增强我们对电气系统的理解。振荡示波阻抗计通过向电路施加交流信号并测量结果电压和电流来工作。通过分析这些参数，它可以计算出阻抗，这是确定电能如何通过电路传输的关键因素。阻抗不仅包括电阻，还考虑了电路中电容器和电感器产生的反应。这种双重性使得阻抗成为比简单电阻更全面的测量。振荡示波阻抗计的重要性不容小觑。在现代电子学中，准确的阻抗测量对于设计高效电路至关重要。例如，在射频（RF）应用中，不匹配的阻抗会导致信号损失和性能下降。工程师使用振荡示波阻抗计确保组件正确匹配，从而优化系统的整体功能。此外，振荡示波阻抗计在研究与开发中也发挥着重要作用。科学家和工程师经常需要分析材料和组件在各种条件下的行为。通过利用该设备，他们可以获得精确的测量结果，从而丰富对材料特性的理解，推动技术创新。例如，超导体及其阻抗特性的研究可以为能源传输和存储领域的突破铺平道路。除了在工程和研究中的应用外，振荡示波阻抗计在教育环境中也非常有价值。学习电气工程的学生可以通过实践操作该仪器，深入了解阻抗测量的实际方面。学习如何操作振荡示波阻抗计有助于加深对理论概念的理解，弥合理论与实践之间的差距。随着技术的不断发展，振荡示波阻抗计可能会进一步增强。数字技术和先进算法的整合可能会导致更准确和高效的测量。此外，设备的小型化可能会使振荡示波阻抗计在各种应用中更加可及，从工业环境到个人项目。总之，振荡示波阻抗计（振荡示波阻抗计）是电气工程领域中不可或缺的工具。它准确测量阻抗的能力为工程师、研究人员和学生打开了无限可能的世界。随着我们继续探索电气系统的复杂性，该设备的重要性只会增加，推动创新并加深我们对支配技术环境的电气现象的理解。