interocular
简明释义
英[ˌɪntərˈɒkjʊlə(r)]美[ˌɪntərˈɑːkjələr]
adj. 两眼间的
英英释义
与眼睛之间的空间有关。 | |
描述涉及双眼的测量或特征。 |
单词用法
眼间距 | |
眼压 | |
眼间镜头 | |
眼间观看 |
同义词
| 双眼的 | 双眼视觉可以提供深度感知。 | ||
| 眼的 | 眼部肌肉控制眼睛运动。 | ||
| 立体的 | 立体图像产生三维效果。 |
反义词
| 眼内的 | Intraocular pressure is an important factor in diagnosing glaucoma. | 眼内压是诊断青光眼的重要因素。 | |
| 单侧的 | 单侧视力丧失可能表明一只眼睛存在问题。 |
例句
1.There are two main categories of cues in the course of stereo vision formation: One is monocular cue, it is the characteristics which can cause depth perception but not need interocular processing.
通常认为引起深度知觉的线索主要有两类:一类为单眼线索,它是指不经双眼性加工就可引起深度知觉的物理特性;
2.The test evaluates the interocular disparity between the two eyes in metamorphopsia.
这种方法对视物变形症两眼之间的视觉差异进行定量。
3.There are two main categories of cues in the course of stereo vision formation: One is monocular cue, it is the characteristics which can cause depth perception but not need interocular processing.
通常认为引起深度知觉的线索主要有两类:一类为单眼线索,它是指不经双眼性加工就可引起深度知觉的物理特性;
4.Interocular competition at the first stage successfully generated rivalry fluctuations in response to traditional rivalry patterns.
第一阶段的两眼间的竞争成功产生了针对传统竞争形式的竞争性波动。
5.The camera settings were adjusted to match the interocular 眼间距 of human vision.
相机设置被调整以匹配人类视觉的眼间距。
6.For accurate depth perception in 3D modeling, the interocular 眼间距 needs to be considered.
为了在3D建模中获得准确的深度感知,需要考虑眼间距。
7.The researcher studied the effects of varying interocular 眼间距 on visual acuity.
研究人员研究了不同的眼间距对视力的影响。
8.In virtual reality, the interocular 眼间距 distance is crucial for creating a realistic experience.
在虚拟现实中,眼间距的距离对于创造真实体验至关重要。
9.The optometrist measured the interocular 眼间距 distance to ensure the correct fit for the glasses.
验光师测量了眼间距的距离,以确保眼镜的正确配合。
作文
The concept of depth perception is a fascinating aspect of human vision, and it relies heavily on the principle of interocular disparity. This term refers to the slight difference in the images perceived by each eye due to their horizontal separation. Our eyes are positioned about six centimeters apart, allowing them to capture two slightly different views of the same scene. This difference is what our brain uses to gauge depth and distance, enabling us to navigate the world with remarkable precision.When we look at an object, each eye sends its own image to the brain. The brain then processes these two images and combines them into a single three-dimensional perception. This process is known as stereopsis, and it is primarily made possible by interocular disparity. For example, if you were to hold your finger in front of your face and alternate closing each eye, you would notice that your finger appears to shift position against the background. This shift is a direct result of the interocular difference in perspective, which helps your brain understand how far away your finger is from you.The importance of interocular disparity extends beyond simple visual perception; it plays a crucial role in various fields such as photography, virtual reality, and even robotics. In photography, capturing images that accurately reflect depth can be achieved through techniques that consider interocular distance. Stereoscopic photography, for instance, involves taking two photographs from slightly different angles and presenting them in a way that mimics our natural vision. When viewed correctly, these images create a sense of depth that is strikingly realistic.In the realm of virtual reality (VR), understanding interocular disparity is essential for creating immersive experiences. VR headsets are designed to replicate the interocular distance of human eyes, providing users with a more convincing and lifelike experience. By presenting two slightly different images to each eye, VR technology can trick the brain into perceiving depth and spatial relationships, making virtual environments feel more real and engaging.Moreover, in robotics and artificial intelligence, machines that mimic human vision must account for interocular disparity to navigate effectively in their environments. Robots equipped with dual cameras can analyze interocular differences to determine distances to objects, which is vital for tasks ranging from autonomous driving to robotic surgery.In conclusion, the term interocular encapsulates a fundamental aspect of how we perceive the world around us. It is not just a technical term used in scientific discussions; rather, it represents a core principle that affects our daily lives, from the way we enjoy movies and photographs to how we interact with technology. Understanding interocular disparity enhances our appreciation of the complexities of human vision and the innovative ways this knowledge is applied across various fields. As we continue to explore the intricacies of sight and perception, the significance of interocular disparity will undoubtedly remain a captivating topic of study and application.
深度感知的概念是人类视觉中一个引人入胜的方面,它在很大程度上依赖于眼间差异的原理。这个术语指的是由于眼睛之间的水平分离而导致的每只眼睛所感知图像的微小差异。我们的眼睛大约相距六厘米,使它们能够捕捉到同一场景的两个略微不同的视图。这种差异是我们的大脑用来判断深度和距离的依据,使我们能够以惊人的精确度在世界中导航。当我们看着一个物体时,每只眼睛都会将自己的图像发送到大脑。然后,大脑处理这两幅图像,并将它们结合成一个单一的三维感知。这个过程被称为立体视觉,而这主要得益于眼间差异。例如,如果你把手指放在脸前面,交替闭上每只眼睛,你会注意到手指在背景中似乎位置发生了变化。这种移动直接是由于眼间视角的差异,这帮助你的大脑理解手指离你有多远。眼间差异的重要性超出了简单的视觉感知;它在摄影、虚拟现实甚至机器人等多个领域中发挥着至关重要的作用。在摄影中,捕捉准确反映深度的图像可以通过考虑眼间距离的技术实现。例如,立体摄影涉及从略微不同的角度拍摄两张照片,并以一种模仿我们自然视觉的方式呈现它们。当正确观看时,这些图像创建出一种引人注目的真实深度感。在虚拟现实(VR)领域,理解眼间差异对于创造沉浸式体验至关重要。VR头盔的设计旨在复制人眼的眼间距离,为用户提供更令人信服和生动的体验。通过向每只眼睛呈现两个略微不同的图像,VR技术可以欺骗大脑感知深度和空间关系,使虚拟环境感觉更加真实和引人入胜。此外,在机器人和人工智能领域,模仿人类视觉的机器必须考虑眼间差异,以有效地在其环境中导航。配备双摄像头的机器人可以分析眼间的差异来确定与物体的距离,这对于从自动驾驶到机器人手术等任务至关重要。总之,术语眼间概括了我们如何感知周围世界的一个基本方面。它不仅仅是科学讨论中使用的技术术语;它代表了一种核心原则,影响着我们的日常生活,从我们享受电影和照片的方式到我们与技术的互动。理解眼间差异增强了我们对人类视觉复杂性的欣赏,以及这种知识在各个领域中的创新应用。随着我们继续探索视觉和感知的复杂性,眼间差异的重要性无疑会继续成为一个引人入胜的研究和应用主题。
