depolarizer

简明释义

英[diˈpɔːləraɪzər]美[diˈpɔːləraɪzər]

n. [助剂] 去极剂；消偏振镜

英英释义

单词用法

同义词

反义词

例句

1.The residual polarization degree of depolarizer is calculated with the matrix optical theory and some factors effecting the depolarizing performance is obtained.

应用矩阵光学推导出了这种紫外石英消偏器的残余偏振度，并得到影响其消偏性能的几个因素。

2.The residual polarization degree of depolarizer is calculated with the matrix optical theory and some factors effecting the depolarizing performance is obtained.

应用矩阵光学推导出了这种紫外石英消偏器的残余偏振度，并得到影响其消偏性能的几个因素。

3.The residual polarization degree of the depolarizer is calculated with matrix optical theory and a good depolarization condition is obtained.

应用矩阵光学理论计算了该消偏器的剩余偏振度，并得到了消偏条件。

4.In this paper, the depolarizing mechanism of the polychromatic light ctystalline quartz rotation depolarizer is studied.

研究了多色光石英旋光退偏器的退偏机理；

5.The principle of wedge depolarizer is introduced;

介绍了楔型晶体退偏器原理；

6.Such a substance is called a depolarizer.

这种物质称为去极剂。

7.The engineer designed a new depolarizer to improve the efficiency of the circuit.

工程师设计了一种新的去极化器以提高电路的效率。

8.In the lab, we tested the depolarizer to see how it affected the signal strength.

在实验室里，我们测试了去极化器，看看它对信号强度的影响。

9.The depolarizer can help reduce the noise in the electronic system.

该去极化器可以帮助减少电子系统中的噪声。

10.Using a depolarizer in the optical setup improved the clarity of the images.

在光学设置中使用去极化器提高了图像的清晰度。

11.The research team discovered that the depolarizer significantly enhanced performance.

研究小组发现去极化器显著增强了性能。

作文

In the field of physics and engineering, the term depolarizer refers to a device or material that reduces or eliminates polarization in light waves. Polarization occurs when light waves vibrate in a particular direction, which can affect how light interacts with various materials. A depolarizer is essential in numerous applications, particularly in optical systems where maintaining the integrity of light is crucial. For instance, in laser technology, the use of a depolarizer helps to ensure that the light emitted is uniform and consistent, improving the quality of the output. The importance of depolarizers can also be seen in photography and imaging. Photographers often utilize filters that serve as depolarizers to reduce glare and reflections from surfaces such as water or glass. By doing so, they can capture images with greater clarity and detail. This application highlights the practical utility of depolarizers in everyday life, beyond their scientific significance. Moreover, in the realm of telecommunications, depolarizers play a crucial role in managing signals. In fiber optic communication, for example, maintaining signal integrity is vital for effective data transmission. The introduction of a depolarizer in these systems can help mitigate issues related to polarization-dependent loss, ensuring that the signals remain strong and reliable over long distances. Understanding how depolarizers work involves delving into the principles of light and optics. When polarized light passes through a depolarizer, the device alters the phase relationship between the light waves, effectively randomizing their orientation. This process results in a mix of different polarization states, leading to a more uniform distribution of light. This fundamental principle is not only fascinating from a scientific perspective but also highlights the intricate relationship between light and matter. Additionally, advancements in technology have led to the development of more sophisticated depolarizers. For instance, liquid crystal depolarizers have emerged as a versatile option in various applications. These devices can be electronically controlled, allowing for dynamic adjustment of the polarization state of light. This capability opens up new possibilities in fields such as virtual reality and augmented reality, where precise control over light behavior is essential. In conclusion, the concept of a depolarizer encompasses a wide range of applications across different fields, from optics and photography to telecommunications. Its ability to manipulate light polarization has significant implications, enhancing the performance and quality of various technologies. As we continue to explore the properties of light and develop new technologies, the role of depolarizers will undoubtedly remain pivotal in shaping the future of optical science and engineering. Understanding and mastering the function of depolarizers not only enriches our knowledge of physics but also empowers us to leverage these tools in innovative ways for practical applications.

在物理和工程领域，术语depolarizer指的是一种减少或消除光波偏振的设备或材料。偏振发生在光波以特定方向振动时，这可能会影响光与各种材料的相互作用。depolarizer在许多应用中至关重要，特别是在光学系统中，其中保持光的完整性至关重要。例如，在激光技术中，使用depolarizer有助于确保发出的光是均匀和一致的，从而提高输出质量。 depolarizers的重要性也体现在摄影和成像中。摄影师经常利用作为depolarizer的滤镜来减少水面或玻璃等表面的眩光和反射。通过这样做，他们可以拍摄出更清晰和细节丰富的图像。这种应用突显了depolarizers在日常生活中的实用性，超越了它们的科学意义。 此外，在电信领域，depolarizers在管理信号方面发挥着关键作用。例如，在光纤通信中，保持信号完整性对于有效数据传输至关重要。在这些系统中引入depolarizer可以帮助减轻与偏振依赖损耗相关的问题，确保信号在长距离内保持强大和可靠。 理解depolarizers的工作原理需要深入研究光和光学的原理。当偏振光通过depolarizer时，该设备改变光波之间的相位关系，有效地随机化其方向。这一过程导致不同偏振状态的混合，从而产生更均匀的光分布。这个基本原理不仅从科学角度令人着迷，还突显了光与物质之间复杂的关系。 此外，技术的进步导致了更复杂的depolarizers的发展。例如，液晶depolarizers作为各种应用中的多功能选项出现。这些设备可以电子控制，允许动态调整光的偏振状态。这种能力为虚拟现实和增强现实等领域打开了新的可能性，其中对光行为的精确控制至关重要。 总之，depolarizer的概念涵盖了不同领域的广泛应用，从光学和摄影到电信。它操纵光偏振的能力具有重要意义，提高了各种技术的性能和质量。随着我们继续探索光的性质并开发新技术，depolarizers的角色无疑在塑造光学科学和工程的未来中将保持关键。理解和掌握depolarizers的功能不仅丰富了我们对物理的知识，还使我们能够以创新的方式利用这些工具进行实际应用。