oscillographic measurement

简明释义

示波测量

英英释义

例句

1.The laboratory specializes in oscillographic measurement for various electronic components.

该实验室专注于各种电子元件的振荡测量。

2.After performing an oscillographic measurement, the team discovered an unexpected distortion in the output signal.

在进行振荡测量后，团队发现输出信号中有意外的失真。

3.The oscillographic measurement revealed critical insights into the performance of the RF circuit.

这次振荡测量揭示了射频电路性能的关键见解。

4.The engineer conducted an oscillographic measurement to analyze the signal waveforms in the circuit.

工程师进行了振荡测量以分析电路中的信号波形。

5.Using oscillographic measurement, we were able to identify the frequency response of the system.

通过振荡测量，我们能够识别系统的频率响应。

作文

In the field of engineering and physics, precise measurements are crucial for understanding complex systems and phenomena. One such method that has gained significant importance is oscillographic measurement, which refers to the technique of recording and analyzing oscillations or waveforms in various systems. This approach is essential in numerous applications, including electronics, telecommunications, and even medical diagnostics. By utilizing oscillographic measurement, engineers can visualize signals, allowing for a better interpretation of the underlying processes that govern their behavior.The fundamental principle behind oscillographic measurement lies in its ability to capture time-varying signals. These signals can be electrical, mechanical, or even biological in nature. For instance, in electronics, an oscilloscope—a device used for oscillographic measurement—displays voltage signals as they change over time. This visualization helps engineers identify anomalies, noise, and other critical characteristics of the signal that may affect the performance of electronic circuits.Moreover, oscillographic measurement plays a vital role in telecommunications. In this context, it is used to analyze the integrity of communication signals, ensuring that data transmission is accurate and reliable. Engineers can detect issues such as signal distortion or interference by examining the waveform patterns captured through oscillographic measurement. This analysis is essential for maintaining the quality of voice calls and internet connectivity, which are integral to modern communication systems.In addition to electronics and telecommunications, oscillographic measurement has significant applications in the medical field. For example, electrocardiograms (ECGs) utilize this technique to measure the electrical activity of the heart. By recording these oscillations, healthcare professionals can diagnose various cardiac conditions and monitor patients' health effectively. The ability to visualize heart rhythms through oscillographic measurement provides invaluable information that can lead to timely interventions and improved patient outcomes.Furthermore, the versatility of oscillographic measurement extends to research and development in various scientific fields. Researchers employ this technique to study oscillatory phenomena in physics, such as sound waves, light waves, and even quantum mechanics. By analyzing these oscillations, scientists can gain insights into fundamental principles governing the universe, leading to advancements in technology and our understanding of nature.However, it is essential to note that oscillographic measurement requires careful calibration and expertise to ensure accurate results. Engineers and scientists must be trained to interpret the data correctly, as misinterpretation can lead to flawed conclusions and potentially hazardous situations. Therefore, proper education and training in oscillographic measurement techniques are paramount for professionals in these fields.In conclusion, oscillographic measurement is a powerful tool that enhances our understanding of dynamic systems across various domains. Its applications in electronics, telecommunications, medicine, and scientific research underscore its significance in modern technology. As we continue to advance in these fields, the importance of mastering oscillographic measurement will only grow, paving the way for innovations that can improve our lives and deepen our understanding of the world around us.

在工程和物理学领域，精确的测量对于理解复杂系统和现象至关重要。其中一种获得重要性的测量方法是振荡测量，它指的是记录和分析各种系统中的振荡或波形的技术。这种方法在电子、电信甚至医学诊断等众多应用中都是必不可少的。通过利用振荡测量，工程师可以可视化信号，从而更好地解释控制其行为的基本过程。振荡测量的基本原理在于它能够捕捉随时间变化的信号。这些信号可以是电气的、机械的，甚至是生物的。例如，在电子学中，示波器——一种用于振荡测量的设备——显示电压信号随时间变化的情况。这种可视化帮助工程师识别异常、噪声以及其他可能影响电子电路性能的关键特征。此外，振荡测量在电信中发挥着至关重要的作用。在这种情况下，它被用来分析通信信号的完整性，确保数据传输的准确性和可靠性。工程师可以通过检查通过振荡测量捕获的波形模式来检测信号失真或干扰等问题。这种分析对于维护语音通话和互联网连接的质量至关重要，而这些都是现代通信系统不可或缺的部分。除了电子学和电信，振荡测量在医学领域也具有重要应用。例如，心电图（ECG）利用这种技术来测量心脏的电活动。通过记录这些振荡，医疗专业人员可以有效地诊断各种心脏病并监测患者的健康。通过振荡测量可视化心律提供了宝贵的信息，这可以导致及时干预和改善患者的健康结果。此外，振荡测量的多功能性扩展到各个科学领域的研究与开发。研究人员利用这一技术研究物理学中的振荡现象，如声波、光波甚至量子力学。通过分析这些振荡，科学家可以深入了解支配宇宙的基本原理，从而推动技术进步和我们对自然的理解。然而，必须注意的是，振荡测量需要仔细校准和专业知识以确保准确的结果。工程师和科学家必须经过培训，以正确解读数据，因为误解可能导致错误的结论和潜在的危险情况。因此，专业人士在这些领域中掌握振荡测量技术的适当教育和培训是至关重要的。总之，振荡测量是一种强大的工具，增强了我们对各个领域动态系统的理解。它在电子学、电信、医学和科学研究中的应用突显了它在现代技术中的重要性。随着我们在这些领域的不断进步，掌握振荡测量的重要性只会增加，为改善我们的生活和加深我们对周围世界的理解铺平道路。