complementary wavelength

简明释义

互补色波长

英英释义

例句

1.The artist chose colors based on their complementary wavelengths 互补波长 to create a vibrant contrast in her painting.

这位艺术家根据颜色的互补波长 互补波长选择颜色，以在她的画作中创造生动的对比。

2.In LED lighting, combining lights of complementary wavelengths 互补波长 can produce a more balanced light spectrum.

在LED照明中，结合互补波长 互补波长的灯光可以产生更均衡的光谱。

3.In color theory, red and cyan are considered complementary wavelengths 互补波长 because they create a neutral gray when mixed.

在色彩理论中，红色和青色被认为是互补波长 互补波长，因为它们混合时会产生中性灰色。

4.Photographers often use filters that allow only complementary wavelengths 互补波长 to pass through, enhancing the colors in their images.

摄影师常常使用只允许通过互补波长 互补波长的滤镜，以增强图像中的颜色。

5.In optics, lenses can be designed to filter out complementary wavelengths 互补波长 to enhance image clarity.

在光学中，可以设计透镜以过滤掉互补波长 互补波长，以增强图像清晰度。

作文

In the realm of physics and optics, the concept of color is intricately linked to the wavelengths of light. One particularly interesting aspect of this relationship is the idea of complementary wavelength, which refers to pairs of colors that, when combined, produce a neutral color such as white or gray. Understanding complementary wavelength is essential not only for artists and designers but also for scientists and engineers who work with light and color in various applications.The human eye perceives color through photoreceptors that respond to specific ranges of wavelengths. For instance, red light has a longer wavelength, while blue light has a shorter one. When we talk about complementary wavelength, we often refer to colors that are opposite each other on the color wheel. This means that when two complementary colors are mixed, they cancel each other out, resulting in a shade of gray or white. For example, the complementary color of blue is orange, and when these two colors are combined in equal measure, they neutralize each other.This phenomenon can be observed in various applications, from painting and graphic design to photography and lighting. Artists often use the principle of complementary wavelength to create contrast and visual interest in their work. By placing complementary colors next to each other, they can enhance the vibrancy of each color, making the artwork more dynamic and engaging. For instance, a bright yellow flower set against a deep purple background will stand out due to the contrast created by their complementary wavelengths.In addition to artistic applications, the concept of complementary wavelength plays a crucial role in technology. In the field of digital imaging, understanding how different wavelengths interact can help improve color accuracy and representation. Cameras and displays rely on the principles of color mixing, and knowing which wavelengths are complementary allows for better calibration and enhancement of images.Furthermore, the study of complementary wavelength is vital in fields like physics and biology. For example, certain species of plants have evolved to attract pollinators by reflecting specific wavelengths of light that are complementary to the vision of those insects. This adaptation not only aids in reproduction but also highlights the interconnectedness of color perception across different organisms.In conclusion, the concept of complementary wavelength serves as a bridge between the worlds of art, science, and technology. It helps us understand how colors interact and influence our perception of the world around us. Whether you are an artist looking to create striking visuals, a photographer aiming for accurate color representation, or a scientist exploring the properties of light, grasping the idea of complementary wavelength is essential. As we continue to explore the complexities of color and light, the significance of complementary wavelengths will undoubtedly remain a fundamental aspect of our understanding of visual experiences.

在物理学和光学领域，颜色的概念与光的波长密切相关。这个关系中一个特别有趣的方面是互补波长的概念，它指的是一对颜色，当它们结合时，会产生一种中性颜色，例如白色或灰色。理解互补波长对于艺术家和设计师以及从事各种光和颜色应用的科学家和工程师来说都是至关重要的。人眼通过对特定波长范围的光敏感的光感受器来感知颜色。例如，红光的波长较长，而蓝光的波长较短。当我们谈论互补波长时，我们通常指的是在色轮上彼此相对的颜色。这意味着当两种互补颜色混合时，它们相互抵消，结果是灰色或白色。例如，蓝色的互补颜色是橙色，当这两种颜色以相等的比例组合时，它们会相互中和。这种现象可以在各种应用中观察到，从绘画和图形设计到摄影和照明。艺术家们常常利用互补波长的原理来创造对比和视觉趣味。通过将互补颜色放在一起，他们可以增强每种颜色的生动性，使作品更加动态和引人入胜。例如，一朵明亮的黄色花朵放在深紫色的背景上，由于它们的互补波长所创造的对比，会显得格外突出。除了艺术应用之外，互补波长的概念在技术领域也发挥着至关重要的作用。在数字成像领域，了解不同波长如何相互作用可以帮助提高颜色的准确性和表现力。相机和显示器依赖于颜色混合的原理，知道哪些波长是互补的可以更好地校准和增强图像。此外，研究互补波长在物理学和生物学等领域也至关重要。例如，某些植物物种已经进化出通过反射特定波长的光来吸引授粉者，这些波长与那些昆虫的视觉是互补的。这种适应不仅有助于繁殖，还突显了不同生物之间颜色感知的相互联系。总之，互补波长的概念在艺术、科学和技术的世界之间架起了一座桥梁。它帮助我们理解颜色如何相互作用并影响我们对周围世界的感知。无论您是希望创造引人注目的视觉效果的艺术家，还是旨在实现准确颜色表现的摄影师，或者是探索光属性的科学家，掌握互补波长的思想都是至关重要的。随着我们继续探索颜色和光的复杂性，互补波长的重要性无疑将始终是我们理解视觉体验的基本方面。