transmission curve

简明释义

透射特性

英英释义

例句

1.The scientist plotted the transmission curve to analyze how different wavelengths of light pass through the material.

科学家绘制了传输曲线以分析不同波长的光如何穿透材料。

2.The transmission curve of the glass shows how much light is absorbed versus transmitted.

玻璃的传输曲线显示了多少光被吸收与透过。

3.Understanding the transmission curve is crucial for developing more efficient solar panels.

理解传输曲线对于开发更高效的太阳能电池板至关重要。

4.In optics, the transmission curve helps in determining the effectiveness of filters.

在光学中，传输曲线有助于确定滤光器的有效性。

5.Engineers use the transmission curve to optimize the performance of communication systems.

工程师使用传输曲线来优化通信系统的性能。

作文

The concept of the transmission curve is fundamental in various fields, including physics, engineering, and even biology. A transmission curve represents the relationship between the input and output of a system, particularly how energy or information is transmitted through a medium. Understanding this curve is essential for optimizing performance in many applications. For instance, in optics, the transmission curve of a material indicates how much light passes through it at different wavelengths. This is crucial for designing lenses and filters that require specific light transmission properties.In telecommunications, the transmission curve can illustrate how signals degrade over distance or through different mediums. Engineers analyze these curves to enhance signal quality and ensure reliable communication. By studying the transmission curve, they can determine the optimal conditions for signal transmission, such as frequency ranges and power levels, which ultimately lead to improved network performance.Moreover, in the field of acoustics, the transmission curve describes how sound waves propagate through various materials. This understanding is vital for architects and sound engineers who strive to create spaces with desirable acoustic properties. By manipulating the transmission curve of materials used in construction, they can control sound absorption and reflection, leading to better auditory experiences in theaters, concert halls, and other venues.In biology, the transmission curve can also refer to the spread of diseases or genetic traits within populations. Epidemiologists study these curves to understand how quickly a disease can spread and what factors influence its transmission. By analyzing the transmission curve, public health officials can implement strategies to control outbreaks and allocate resources effectively.The significance of the transmission curve extends beyond theoretical applications; it has practical implications in everyday life. For example, when purchasing electronic devices, consumers often consider specifications related to data transmission rates, which are influenced by the transmission curve of the technology used. Understanding how different devices perform in terms of their transmission curve can help consumers make informed choices.In conclusion, the transmission curve is a versatile concept that plays a crucial role in various disciplines. Whether in optics, telecommunications, acoustics, or biology, understanding the transmission curve allows professionals to optimize systems, enhance performance, and make informed decisions. As technology continues to evolve, the importance of mastering this concept will only grow, highlighting the need for interdisciplinary collaboration and research. Therefore, studying the transmission curve not only enriches our knowledge but also equips us with the tools necessary to tackle complex challenges in an increasingly interconnected world.

“传输曲线”这一概念在物理学、工程学甚至生物学等多个领域中都是基础性的。“传输曲线”表示输入和输出之间的关系，特别是能量或信息如何通过介质进行传递。理解这一曲线对于优化许多应用中的性能至关重要。例如，在光学中，材料的“传输曲线”指示不同波长的光透过它的程度。这对于设计需要特定光传输特性的透镜和滤光片至关重要。在电信领域，“传输曲线”可以说明信号在距离或不同介质中衰减的情况。工程师分析这些曲线以增强信号质量，确保可靠的通信。通过研究“传输曲线”，他们可以确定信号传输的最佳条件，例如频率范围和功率水平，这最终导致网络性能的提升。此外，在声学领域，“传输曲线”描述了声波如何通过各种材料传播。这种理解对建筑师和声学工程师至关重要，他们努力创造具有理想声学特性的空间。通过操控建筑材料的“传输曲线”，他们可以控制声音的吸收和反射，从而在剧院、音乐厅和其他场所创造更好的听觉体验。在生物学中，“传输曲线”也可以指疾病或遗传特征在种群中的传播。流行病学家研究这些曲线以了解疾病传播的速度以及影响其传播的因素。通过分析“传输曲线”，公共卫生官员可以实施控制疫情的策略，并有效分配资源。“传输曲线”的重要性不仅限于理论应用；它在日常生活中也有实际意义。例如，在购买电子设备时，消费者通常会考虑与数据传输速率相关的规格，而这些速率受到所用技术的“传输曲线”的影响。理解不同设备在其“传输曲线”方面的表现可以帮助消费者做出明智的选择。总之，“传输曲线”是一个多功能的概念，在多个学科中发挥着关键作用。无论是在光学、电信、声学还是生物学中，理解“传输曲线”使专业人士能够优化系统、提高性能并做出明智的决策。随着技术的不断发展，掌握这一概念的重要性只会增加，突显出跨学科合作和研究的必要性。因此，研究“传输曲线”不仅丰富了我们的知识，还为我们提供了应对日益互联世界中复杂挑战所需的工具。