achromatization

简明释义

英[əˌkrəʊmətaɪˈzeɪʃən]美[əˌkromətɪˈzeʃən]

[光] 消色差化

[光] 消色差

英英释义

单词用法

同义词

反义词

例句

1.A dispersion correcting circuit of SLO is presented. The circuit can compensate achromatization produced by the acoustooptic deflector and enhance sharpness of the colour image for better diagnosis.

本文介绍了一种激光扫描检眼仪的消色散电路。该电路可补偿声光偏转器产生的色散，提高彩色图像的清晰度，增强该仪器的辅助诊断作用。

2.The diffractive optical elements(DOEs) used in imaging systems has many advantages, such as achromatization and thermal compensation besides the features of saving in mass and volume.

采用衍射光学元件除了能减小成像系统的体积和重量外 ，还具有许多传统光学元件无法比拟的优越性 ，如消色差和热补偿功能等。

3.A dispersion correcting circuit of SLO is presented. The circuit can compensate achromatization produced by the acoustooptic deflector and enhance sharpness of the colour image for better diagnosis.

本文介绍了一种激光扫描检眼仪的消色散电路。该电路可补偿声光偏转器产生的色散，提高彩色图像的清晰度，增强该仪器的辅助诊断作用。

4.The process of achromatization is crucial in optical design to minimize chromatic aberration.

光学设计中的achromatization过程对于最小化色差至关重要。

5.The achromatization of lenses allows for better focus across different wavelengths of light.

镜头的achromatization允许在不同波长的光线下获得更好的聚焦。

6.In photography, achromatization can help produce clearer images by reducing color distortions.

在摄影中，achromatization可以通过减少色彩失真来帮助产生更清晰的图像。

7.The achromatization technique is often used in the production of high-quality telescopes.

在高质量望远镜的生产中，常常使用achromatization技术。

8.Scientists are researching new materials that enhance achromatization in optical systems.

科学家们正在研究新材料，以增强光学系统中的achromatization。

作文

The concept of achromatization plays a significant role in various scientific fields, particularly in optics and materials science. In essence, achromatization refers to the process of eliminating color or chromatic aberration from optical systems, thereby allowing for clearer and more accurate imaging. This phenomenon is crucial in the development of high-quality lenses and optical instruments, such as cameras, microscopes, and telescopes. By understanding achromatization, scientists and engineers can create devices that provide sharper images without the distortions caused by different wavelengths of light.In the realm of optics, achromatization is achieved through the use of special lens designs and materials. For instance, an achromatic lens typically consists of two or more lens elements made from different types of glass with varying refractive indices. These elements are carefully shaped and positioned to counteract the effects of chromatic aberration, which occurs when light of different colors is focused at different points. The result is a lens that produces images with minimal color distortion, enhancing the overall quality of the visual output.Furthermore, achromatization is not limited to optical systems alone; it also finds applications in the field of materials science. In this context, achromatization can refer to the modification of materials to reduce their color properties, making them more suitable for specific applications. For example, in the production of certain polymers or coatings, achieving an achromatic state can improve the material's performance by ensuring that it does not absorb or reflect unwanted wavelengths of light.The significance of achromatization extends beyond technical applications; it also has implications for art and design. Artists and designers often seek to achieve a harmonious balance of colors in their work, and understanding the principles of achromatization can aid in this pursuit. By manipulating color and light, they can create visually striking compositions that resonate with viewers on a deeper level.In conclusion, achromatization is a multifaceted concept that encompasses both scientific and artistic endeavors. Its importance in optics cannot be overstated, as it enables the creation of high-performance optical instruments that enhance our ability to observe and understand the world around us. Additionally, its relevance in materials science and design highlights the interconnectedness of these fields, showcasing how the principles of achromatization can lead to advancements in technology and creativity. As we continue to explore the boundaries of science and art, the understanding and application of achromatization will undoubtedly play a pivotal role in shaping our future innovations and expressions.

“去色化”这个概念在多个科学领域中发挥着重要作用，特别是在光学和材料科学中。本质上，achromatization指的是消除光学系统中的颜色或色差的过程，从而实现更清晰和更准确的成像。这一现象对于高质量镜头和光学仪器的发展至关重要，例如相机、显微镜和望远镜。通过理解achromatization，科学家和工程师可以创造出提供更清晰图像的设备，而不受不同波长光线引起的失真影响。在光学领域，achromatization是通过使用特殊的镜头设计和材料来实现的。例如，消色差镜头通常由两个或多个不同类型的玻璃制成的镜头元件组成，这些玻璃具有不同的折射率。这些元件经过精心塑形和定位，以抵消色差的影响，即不同颜色的光在不同点聚焦的现象。其结果是产生色彩失真最小的图像，增强了视觉输出的整体质量。此外，achromatization不仅限于光学系统；它在材料科学领域也有应用。在这种情况下，achromatization可以指对材料进行修改，以减少其颜色特性，使其更适合特定应用。例如，在某些聚合物或涂层的生产中，实现去色化状态可以通过确保材料不会吸收或反射不必要的光波长来提高其性能。achromatization的重要性不仅限于技术应用；它还对艺术和设计产生影响。艺术家和设计师常常寻求在作品中实现色彩的和谐平衡，理解achromatization的原理可以帮助他们追求这一目标。通过操控颜色和光线，他们可以创作出视觉上引人注目的作品，与观众产生更深层次的共鸣。总之，achromatization是一个多方面的概念，涵盖了科学和艺术的努力。它在光学中的重要性不言而喻，因为它使得高性能光学仪器的创造成为可能，增强了我们观察和理解周围世界的能力。此外，它在材料科学和设计中的相关性突显了这些领域之间的相互联系，展示了achromatization的原则如何推动技术和创造力的进步。随着我们继续探索科学和艺术的边界，对achromatization的理解和应用无疑将在塑造我们未来的创新和表达中发挥关键作用。