transmission experiment

简明释义

透射实验

英英释义

例句

1.During the transmission experiment, scientists observed how sound waves traveled through various mediums.

在这项传播实验中，科学家观察了声波如何通过各种介质传播。

2.The transmission experiment revealed unexpected results regarding the behavior of electromagnetic waves.

这项传播实验揭示了电磁波行为的意外结果。

3.In the physics lab, we set up a transmission experiment to measure the speed of light through different materials.

在物理实验室，我们设置了一项传播实验，以测量光在不同材料中的速度。

4.The team published their findings from the transmission experiment in a leading scientific journal.

团队将他们在这项传播实验中的发现发表在一家知名科学期刊上。

5.The researchers conducted a transmission experiment to study how viruses spread in a controlled environment.

研究人员进行了一项传播实验，以研究病毒在受控环境中的传播方式。

作文

In the field of science, particularly in physics and communications, the term transmission experiment refers to a methodical investigation designed to understand how information or energy is transmitted from one point to another. These experiments are crucial for the development of various technologies, including telecommunications, broadcasting, and even quantum mechanics. The significance of transmission experiment lies not only in its practical applications but also in its theoretical implications. Through these experiments, scientists can explore the fundamental principles of wave propagation, signal integrity, and data encoding.One of the most notable examples of a transmission experiment is the study of radio waves. When researchers first began experimenting with radio transmissions, they were eager to understand how electromagnetic waves could carry information over long distances. They conducted numerous tests to determine the optimal frequency, modulation techniques, and antenna designs necessary for effective transmission. These early transmission experiments laid the groundwork for modern radio communication systems.In addition to radio waves, transmission experiments have been pivotal in the realm of optical communications. With the advent of fiber optics, scientists have conducted extensive experiments to assess how light signals can be transmitted through glass fibers with minimal loss. These experiments involve varying factors such as wavelength, refractive index, and environmental conditions to optimize the performance of fiber optic systems. The results of these transmission experiments have revolutionized internet connectivity, allowing for faster and more reliable data transfer.Furthermore, transmission experiments are not limited to classical physics; they also play a significant role in quantum mechanics. Researchers have been investigating quantum entanglement and superposition through various transmission experiments. For instance, scientists have used photons to test theories about how quantum information can be transmitted without being disturbed. These groundbreaking experiments challenge our understanding of reality and open up new possibilities for secure communication systems, such as quantum cryptography.The design of a transmission experiment typically involves several key components: the source of the signal, the medium through which the signal travels, and the receiver that captures the transmitted information. Each component must be carefully calibrated to ensure accurate results. For example, in a typical radio transmission experiment, researchers must select an appropriate transmitter to generate the signal, choose a suitable environment to minimize interference, and employ a receiver capable of detecting the signal at varying distances.Moreover, the analysis of data obtained from transmission experiments is essential for improving existing technologies. By examining the outcomes of these experiments, engineers can identify potential issues, such as signal degradation or interference, and develop strategies to mitigate these problems. This iterative process of experimentation and analysis is foundational to advancements in technology and helps pave the way for innovations in communication systems.In conclusion, the concept of transmission experiment is integral to our understanding of how information and energy are conveyed across different mediums. From the early days of radio to the cutting-edge developments in quantum communication, these experiments have provided invaluable insights that have shaped modern technology. As we continue to explore the frontiers of science, the importance of transmission experiments will undoubtedly remain a cornerstone of research and innovation in the years to come.

在科学领域，特别是在物理学和通信中，术语传输实验指的是一种系统的调查，旨在理解信息或能量是如何从一个点传输到另一个点的。这些实验对于各种技术的发展至关重要，包括电信、广播甚至量子力学。传输实验的重要性不仅在于其实际应用，还在于其理论意义。通过这些实验，科学家可以探索波传播、信号完整性和数据编码的基本原理。一个最显著的传输实验例子是对无线电波的研究。当研究人员首次开始进行无线电传输实验时，他们急于了解电磁波如何能够在长距离上传递信息。他们进行了大量测试，以确定有效传输所需的最佳频率、调制技术和天线设计。这些早期的传输实验为现代无线电通信系统奠定了基础。除了无线电波，传输实验在光通信领域也起着关键作用。随着光纤技术的出现，科学家们进行了广泛的实验，以评估光信号如何能够以最小损耗通过玻璃光纤传输。这些实验涉及变化波长、折射率和环境条件等因素，以优化光纤系统的性能。这些传输实验的结果彻底改变了互联网连接，使数据传输更快、更可靠。此外，传输实验不仅限于经典物理；它们在量子力学中也扮演着重要角色。研究人员一直在通过各种传输实验研究量子纠缠和叠加。例如，科学家们使用光子来检验关于量子信息如何在不被干扰的情况下传输的理论。这些开创性的实验挑战了我们对现实的理解，并为安全通信系统（如量子密码术）开辟了新的可能性。传输实验的设计通常涉及几个关键组件：信号源、信号传播的介质以及捕获传输信息的接收器。每个组件都必须经过仔细校准，以确保结果的准确性。例如，在典型的无线电传输实验中，研究人员必须选择合适的发射器来生成信号，选择合适的环境以最小化干扰，并使用能够在不同距离检测信号的接收器。此外，对从传输实验中获得的数据进行分析对于改进现有技术至关重要。通过检查这些实验的结果，工程师可以识别潜在问题，例如信号衰减或干扰，并制定策略来减轻这些问题。这一实验和分析的迭代过程是技术进步的基础，有助于为通信系统的创新铺平道路。总之，传输实验的概念对于我们理解信息和能量如何通过不同介质传递至关重要。从早期的无线电到量子通信的前沿发展，这些实验提供了宝贵的见解，塑造了现代技术。随着我们继续探索科学的前沿，传输实验的重要性无疑将继续成为未来研究和创新的基石。