photogrammetric

简明释义

英[/ˌfoʊtəˈɡræmɛtrɪk/]美[/ˌfoʊtəˈɡræmɛtrɪk/]

adj. 摄影制图的，摄影测量的

英英释义

单词用法

同义词

反义词

例句

1.At recent years, the close-range photogrammetric technology is widely used in many fields as a non-contact and high-accuracy method of measurement.

近年来，近景摄影测量技术作为一种非接触高精度的测量方法在各行各业都有着广泛的应用。

2.In this paper, the main study is the development of auto 3d Moddeling software based on the data that collect through Digital Photogrammetric Work Station.

本文主要研究了如何以数字摄影测量工作站获取的建筑物三维数据为基础来开发建筑物三维模型自动生成软件。

3.This paper has dealt with the short-range high speed photogrammetric system for large-scale rocket launching lateral drift-magnitude and the data processing method.

本文论及了大型火箭发射起飞段横向漂移量的近距离高速摄影测量系统和数据处理方法。

4.The compressed encoding of image data is one of the most important ring - joint of digital photogrammetric surveying field.

图像数据压缩编码是数字摄影测量领域的关键环节之一。

5.Based on the principle of photogrammetry, the author establishes a photogrammetric surveying system of higher degree of automation. which can better solve these problems.

本文作者根据摄影测量原理。建立了一个自动化程度较高的摄影测量系统。该系统可以较好地解决这些问题。

6.According to the main factors which affect the mapping precision, it is shown that difference between the digital photogrammetry mapping and analog photogrammetric plotting is comparatively analysed.

结合生产实践，从影响成图精度的几种因素的估算方法入手，比较分析了全数字化测图仪器同模拟测图仪器之间的精度差别。

7.In this paper, a method used for determination of accuracy of DEM data derived from digitized frame photos (or digital image) by digital photogrammetric systems has been developed.

论述一个由数字化画幅式像片(或数字影像)用数字摄影测量系统生成的DEM数据精度的确定方法。

8.The photogrammetric model of computer vision is the fundamental for traffic accident sence measurement system.

计算机视觉摄影测量模型是通过计算机视觉进行事故现场测量系统设计的基础。

9.For an active control of the gripper beyond the point where photogrammetric positioning is possible, i. e. when it clamps or touches an object, force sensing would be of great advantage.

为积极的控制的地步片梭超越摄影测量定位是可能的，即当它夹或触动一个物体，遥控焊接力觉会极大的好处。

10.The team used photogrammetric 摄影测量的 techniques to create a detailed map of the area.

团队使用摄影测量的技术制作了该地区的详细地图。

11.By employing photogrammetric 摄影测量的 methods, they were able to capture accurate 3D models of the buildings.

通过采用摄影测量的方法，他们能够捕捉到建筑物的准确3D模型。

12.The photogrammetric 摄影测量的 analysis provided valuable data for the construction project.

该摄影测量的分析为建设项目提供了宝贵的数据。

13.Using photogrammetric 摄影测量的 surveys, archaeologists can reconstruct ancient sites.

考古学家可以利用摄影测量的调查重建古代遗址。

14.The photogrammetric 摄影测量的 software allowed for precise measurements from aerial images.

该摄影测量的软件允许从航空图像中进行精确测量。

作文

In recent years, the field of surveying and mapping has seen significant advancements, particularly with the integration of technology. One of the most fascinating developments is the use of photogrammetric techniques, which allow for the extraction of three-dimensional information from two-dimensional images. This process not only enhances the accuracy of measurements but also improves the efficiency of data collection. Photogrammetric methods are widely utilized in various applications, including topographic mapping, urban planning, and even environmental monitoring. The essence of photogrammetric analysis lies in its ability to convert photographs into precise spatial data. By capturing images from different angles and using specialized software, surveyors can create detailed models of the terrain. This is particularly useful in areas that are difficult to access, as it eliminates the need for extensive fieldwork. Additionally, photogrammetric methods can be employed in aerial surveys, where drones or aircraft capture high-resolution images of large areas, making the process faster and more cost-effective. One of the key advantages of photogrammetric techniques is their versatility. They can be applied to various fields, including architecture, archaeology, and agriculture. For instance, in archaeology, photogrammetric methods can document historical sites without causing damage, allowing researchers to create accurate records of artifacts and structures. Similarly, in agriculture, farmers can use photogrammetric imaging to monitor crop health and assess land use, leading to better resource management and increased yields. Moreover, the accuracy of photogrammetric data has improved significantly due to advancements in imaging technology. High-resolution cameras and sophisticated algorithms enable surveyors to achieve centimeter-level precision in their measurements. This level of accuracy is crucial for projects that require meticulous planning and execution, such as infrastructure development and natural resource management. Despite its many benefits, the adoption of photogrammetric techniques is not without challenges. The initial investment in equipment and software can be substantial, which may deter some organizations from fully embracing this technology. Furthermore, there is a learning curve associated with mastering the necessary skills to conduct photogrammetric analyses effectively. Training and education are essential to ensure that professionals in the field can leverage these tools to their fullest potential. Looking ahead, the future of photogrammetric techniques appears promising. As technology continues to evolve, we can expect even greater accuracy and efficiency in data collection. The integration of artificial intelligence and machine learning into photogrammetric processes could revolutionize the way we analyze and interpret spatial data. This would not only enhance the capabilities of surveyors but also open up new possibilities for interdisciplinary collaboration across various sectors. In conclusion, the use of photogrammetric techniques represents a significant leap forward in the field of surveying and mapping. Their ability to transform photographs into accurate spatial data has far-reaching implications for numerous industries. While challenges remain in terms of cost and training, the potential benefits of adopting photogrammetric methods are undeniable. As we continue to explore and innovate within this field, we can look forward to a future where photogrammetric techniques play an increasingly vital role in shaping our understanding of the world around us.

近年来，测绘领域见证了重大的进步，特别是在技术整合方面。其中一个最令人着迷的发展是使用摄影测量技术，它允许从二维图像中提取三维信息。这个过程不仅提高了测量的准确性，还改善了数据收集的效率。摄影测量方法广泛应用于各种领域，包括地形测绘、城市规划，甚至环境监测。 摄影测量分析的本质在于其将照片转化为精确空间数据的能力。通过从不同角度捕捉图像并使用专业软件，测量员可以创建详细的地形模型。这在难以到达的地区尤为有用，因为它消除了大量现场工作的需要。此外，摄影测量方法还可以用于航空调查，其中无人机或飞机捕获大面积的高分辨率图像，使得过程更快且更具成本效益。 摄影测量技术的一个关键优势是其多功能性。它们可以应用于建筑、考古学和农业等多个领域。例如，在考古学中，摄影测量方法可以在不造成损害的情况下记录历史遗址，使研究人员能够创建文物和结构的准确记录。同样，在农业中，农民可以使用摄影测量成像监测作物健康和评估土地利用，从而实现更好的资源管理和提高产量。 此外，由于成像技术的进步，摄影测量数据的准确性显著提高。高分辨率相机和复杂算法使测量员能够达到厘米级的精度。这种精度对于需要细致规划和执行的项目至关重要，例如基础设施开发和自然资源管理。 尽管有许多好处，摄影测量技术的采用并非没有挑战。设备和软件的初始投资可能很可观，这可能会阻止一些组织充分采用这一技术。此外，掌握有效进行摄影测量分析所需的技能也有一定的学习曲线。培训和教育对于确保该领域的专业人士能够充分利用这些工具至关重要。 展望未来，摄影测量技术的前景似乎非常光明。随着技术的不断发展，我们可以期待数据收集的准确性和效率进一步提高。将人工智能和机器学习整合到摄影测量过程中可能会彻底改变我们分析和解释空间数据的方式。这不仅将增强测量员的能力，还将为各个行业之间的跨学科合作开辟新的可能性。 总之，使用摄影测量技术代表了测绘领域的一次重大飞跃。它们将照片转化为准确空间数据的能力对众多行业具有深远的影响。尽管在成本和培训方面仍然存在挑战，但采用摄影测量方法的潜在好处是不可否认的。随着我们继续探索和创新这一领域，我们可以期待未来摄影测量技术在塑造我们对周围世界的理解中发挥越来越重要的作用。