transmission holography

简明释义

透射全息照相术

英英释义

例句

1.Researchers are developing new techniques in transmission holography 透射全息术 to improve the resolution of holographic images.

研究人员正在开发新的技术来提高transmission holography 透射全息术 全息图像的分辨率。

2.In medicine, transmission holography 透射全息术 is being used to create detailed images of tissues for diagnostic purposes.

在医学中，transmission holography 透射全息术 被用于创建详细的组织图像以供诊断使用。

3.The application of transmission holography 透射全息术 in telecommunications allows for better data transmission rates.

在电信中应用transmission holography 透射全息术 可以实现更好的数据传输速率。

4.In the field of art, artists are exploring the use of transmission holography 透射全息术 to create three-dimensional images that can be viewed from different angles.

在艺术领域，艺术家们正在探索使用transmission holography 透射全息术 创建可以从不同角度观看的三维图像。

5.The film industry is experimenting with transmission holography 透射全息术 to produce stunning visual effects for movies.

电影行业正在尝试使用transmission holography 透射全息术 制作惊艳的视觉效果。

作文

In the realm of optics and imaging, holography stands out as a revolutionary technique that captures and reproduces three-dimensional images. Among the various types of holography, transmission holography is particularly significant due to its unique method of recording and reconstructing light fields. This approach involves the use of a laser to illuminate an object, with the reflected light being recorded on a photosensitive medium. The resulting hologram contains all the information necessary to recreate the original scene when illuminated by a coherent light source, such as a laser. The process of transmission holography begins with the coherent light beam from a laser, which is split into two paths: the object beam and the reference beam. The object beam is directed towards the object, and the light that reflects off the object interacts with the reference beam on the photosensitive medium. This interference pattern created by the overlapping beams encodes the amplitude and phase information of the light waves, which is essential for reconstructing the three-dimensional image later on.One of the key advantages of transmission holography is its ability to produce high-resolution images with depth perception. When a viewer looks at the hologram under appropriate lighting conditions, they can see a vivid representation of the object, complete with its spatial characteristics. This feature makes transmission holography invaluable in various applications, including art, security, and scientific research.In the field of art, artists have begun to explore the aesthetic potential of transmission holography. By creating holographic artworks, they can offer viewers a dynamic experience where the perception of the image changes based on the viewer's angle and distance. This interactive quality adds a new dimension to traditional art forms, allowing for a more immersive experience.Security is another area where transmission holography plays a crucial role. Holograms are widely used in banknotes, credit cards, and identification documents to prevent counterfeiting. The intricate details of the holographic images make it extremely difficult for counterfeiters to replicate, thus providing an added layer of security.Furthermore, in scientific research, transmission holography has proven to be a powerful tool for studying microscopic structures. By using this technique, scientists can observe and analyze biological specimens, materials, and other intricate systems without the need for invasive procedures. This capability allows for a better understanding of complex phenomena in fields such as biology, materials science, and physics.Despite its numerous advantages, transmission holography also faces challenges. The requirement for coherent light sources, such as lasers, limits its accessibility for some applications. Additionally, the process of creating and viewing holograms can be complex, requiring specialized equipment and knowledge.In conclusion, transmission holography represents a fascinating intersection of art and science, offering unique capabilities for capturing and displaying three-dimensional images. Its applications span various fields, from artistic expression to security measures and scientific exploration. As technology advances, it is likely that transmission holography will continue to evolve, opening up new possibilities for innovation and creativity in the visual domain.

在光学和成像领域， holography（全息摄影）作为一种革命性技术，能够捕捉和再现三维图像。 在各种类型的全息摄影中， transmission holography（透射全息摄影）因其独特的记录和重建光场的方法而显得尤为重要。 这种方法涉及使用激光照射物体，反射光被记录在光敏介质上。 生成的全息图包含再现原始场景所需的所有信息，当用相干光源（如激光）照明时，可以重构该图像。transmission holography（透射全息摄影）的过程始于来自激光的相干光束，该光束被分成两条路径：物体光束和参考光束。 物体光束指向物体，反射回来的光与参考光束在光敏介质上相互作用。 这种重叠光束产生的干涉图案编码了光波的幅度和相位信息，这对于稍后重构三维图像至关重要。transmission holography（透射全息摄影）的一个主要优势是它能够产生具有深度感的高分辨率图像。 当观众在适当的照明条件下观看全息图时，他们可以看到物体的生动表现，连同其空间特征。 这一特性使得transmission holography（透射全息摄影）在艺术、安全和科学研究等各个应用中都显得非常重要。在艺术领域，艺术家们开始探索transmission holography（透射全息摄影）的美学潜力。 通过创作全息艺术作品，他们可以为观众提供一种动态体验，图像的感知会根据观众的角度和距离而变化。 这种互动特性为传统艺术形式增添了新维度，使体验更加沉浸。安全性是transmission holography（透射全息摄影）发挥关键作用的另一个领域。 全息图广泛用于钞票、信用卡和身份证件中，以防止伪造。 全息图像的复杂细节使得伪造者极难复制，从而提供了额外的安全层。此外，在科学研究中，transmission holography（透射全息摄影）已被证明是研究微观结构的强大工具。 通过使用此技术，科学家可以观察和分析生物样本、材料和其他复杂系统，而无需进行侵入性程序。 这一能力使得在生物学、材料科学和物理学等领域更好地理解复杂现象成为可能。尽管有许多优点，transmission holography（透射全息摄影）也面临挑战。 对相干光源（如激光）的需求限制了其在某些应用中的可及性。 此外，创建和查看全息图的过程可能很复杂，需要专业设备和知识。总之，transmission holography（透射全息摄影）代表了艺术与科学的迷人交集，提供了捕捉和展示三维图像的独特能力。 它的应用跨越多个领域，从艺术表现到安全措施，再到科学探索。 随着技术的进步，transmission holography（透射全息摄影）可能会继续发展，为视觉领域的创新和创造力开辟新的可能性。