precision scanning
简明释义
精密扫描
英英释义
Precision scanning refers to a method of capturing detailed and accurate data from an object or environment using advanced imaging technology. | 精确扫描是指使用先进成像技术从物体或环境中捕获详细且准确数据的方法。 |
例句
1.In archaeology, precision scanning 精确扫描 helps preserve artifacts without physical contact.
在考古学中,精确扫描帮助在不接触的情况下保护文物。
2.The laboratory uses precision scanning 精确扫描 technology to analyze microscopic samples.
实验室使用精确扫描技术来分析微观样本。
3.The medical facility employs precision scanning 精确扫描 to improve diagnostic imaging.
该医疗机构采用精确扫描来改善诊断成像。
4.With precision scanning 精确扫描, we can create highly detailed 3D models of objects.
通过精确扫描,我们可以创建物体的高细节3D模型。
5.The new printer features precision scanning 精确扫描 capabilities for high-quality image reproduction.
这款新打印机具有精确扫描能力,以实现高质量的图像复制。
作文
In the modern world, technology has transformed various fields, including healthcare, manufacturing, and research. One of the significant advancements in these areas is the concept of precision scanning, which refers to the use of advanced imaging techniques to capture highly detailed and accurate representations of objects or environments. This process is crucial in many applications, from medical diagnostics to quality control in manufacturing. Understanding precision scanning is essential for appreciating its impact on our daily lives and the industries that shape them.In healthcare, precision scanning plays a vital role in diagnosing diseases and planning treatments. For instance, techniques such as MRI (Magnetic Resonance Imaging) and CT (Computed Tomography) scans provide doctors with detailed images of a patient's internal structures. These images allow for precise identification of abnormalities, such as tumors or fractures, leading to more accurate diagnoses. The precision offered by these scanning methods can significantly influence treatment decisions, ensuring patients receive the most effective care tailored to their specific conditions.Moreover, precision scanning is not limited to the medical field. In manufacturing, it is used to ensure that products meet stringent quality standards. For example, laser scanning technology can measure the dimensions of components with extreme accuracy. This precision is crucial in industries such as aerospace and automotive, where even the slightest deviation from specifications can lead to catastrophic failures. By implementing precision scanning techniques, manufacturers can enhance product reliability and safety, ultimately improving customer satisfaction.In addition to healthcare and manufacturing, precision scanning is also making waves in the realm of research and archaeology. Researchers utilize this technology to create detailed 3D models of artifacts or historical sites, allowing for better analysis and preservation. For instance, using laser scanners, archaeologists can capture the intricate details of ancient ruins without disturbing the site. This non-invasive approach not only aids in documentation but also helps in virtual reconstructions, providing insights into past civilizations.Furthermore, the rise of precision scanning has also led to innovations in fields like robotics and autonomous vehicles. These systems rely on precise environmental scanning to navigate and make decisions. LiDAR (Light Detection and Ranging) technology, for example, uses laser light to measure distances with high accuracy, enabling self-driving cars to detect obstacles and understand their surroundings effectively. This level of precision is paramount for ensuring safety and efficiency in transportation.In conclusion, precision scanning is a transformative technology that enhances accuracy and detail across various sectors. Its applications in healthcare, manufacturing, research, and autonomous systems demonstrate its versatility and significance. As technology continues to advance, the importance of precision scanning will likely grow, paving the way for new innovations and improved outcomes in numerous fields. Embracing this technology will undoubtedly lead to a future where precision and accuracy are paramount, benefiting society as a whole.
在现代世界中,技术已经改变了多个领域,包括医疗、制造和研究。其中一个重要的进展是精密扫描的概念,它指的是使用先进的成像技术捕捉物体或环境的高度详细和准确的表示。这一过程在许多应用中至关重要,从医学诊断到制造质量控制。理解精密扫描对于欣赏它对我们日常生活和塑造这些行业的影响至关重要。在医疗保健中,精密扫描在疾病诊断和治疗计划中发挥着重要作用。例如,MRI(磁共振成像)和CT(计算机断层扫描)等技术为医生提供了患者内部结构的详细图像。这些图像允许精确识别异常情况,如肿瘤或骨折,从而导致更准确的诊断。这些扫描方法提供的精度可以显著影响治疗决策,确保患者接受最有效的、针对其特定病情的护理。此外,精密扫描不仅限于医疗领域。在制造业中,它用于确保产品符合严格的质量标准。例如,激光扫描技术可以极其准确地测量组件的尺寸。这种精度在航空航天和汽车等行业中至关重要,因为即使是微小的规格偏差也可能导致灾难性的故障。通过实施精密扫描技术,制造商可以增强产品的可靠性和安全性,最终提高客户满意度。除了医疗和制造业,精密扫描在研究和考古领域也引起了轰动。研究人员利用这项技术创建文物或历史遗址的详细3D模型,从而更好地进行分析和保存。例如,考古学家可以使用激光扫描仪捕捉古代遗址的复杂细节,而不干扰现场。这种非侵入性的方法不仅有助于文档记录,还帮助进行虚拟重建,为了解过去的文明提供了见解。此外,精密扫描的兴起还推动了机器人和自动驾驶汽车等领域的创新。这些系统依赖于精确的环境扫描来导航和做出决策。例如,LiDAR(光探测与测距)技术利用激光光线以高精度测量距离,使自动驾驶汽车能够有效地检测障碍物并理解其周围环境。这种精度对于确保交通安全和效率至关重要。总之,精密扫描是一项变革性的技术,它在各个领域提升了准确性和细节。它在医疗、制造、研究和自主系统中的应用展示了它的多样性和重要性。随着技术的不断进步,精密扫描的重要性可能会不断增长,为众多领域的新创新和改进成果铺平道路。拥抱这项技术无疑将导致一个精度和准确性至关重要的未来,造福整个社会。
相关单词
