ultrasonic holography

简明释义

超声全息照相术

英英释义

例句

1.The application of ultrasonic holography 超声全息术 in art conservation has opened new avenues for restoration techniques.

在艺术保护中应用ultrasonic holography超声全息术为修复技术开辟了新的途径。

2.Using ultrasonic holography 超声全息术, researchers were able to create detailed images of the bone structure.

研究人员利用ultrasonic holography超声全息术能够创建骨骼结构的详细图像。

3.In medical imaging, ultrasonic holography 超声全息术 offers a non-invasive way to examine organs in real time.

在医学成像中，ultrasonic holography超声全息术提供了一种无创的方法来实时检查器官。

4.The research team utilized ultrasonic holography 超声全息术 to visualize the internal structures of complex materials.

研究团队利用ultrasonic holography超声全息术来可视化复杂材料的内部结构。

5.The engineer explained how ultrasonic holography 超声全息术 could improve the detection of flaws in manufacturing processes.

工程师解释了ultrasonic holography超声全息术如何改善制造过程中缺陷的检测。

作文

In the realm of advanced imaging techniques, ultrasonic holography stands out as a remarkable innovation that combines the principles of ultrasound and holography to create detailed images of objects and structures. This technique utilizes high-frequency sound waves to capture the three-dimensional characteristics of an object, allowing for a non-invasive examination that is invaluable in various fields such as medicine, engineering, and materials science. The essence of ultrasonic holography lies in its ability to produce a holographic representation, which provides depth information and enhances the visualization of complex shapes and internal features. The process begins with the emission of ultrasonic waves towards the target object. These waves interact with the object, reflecting back to the sensor where the data is collected. By analyzing the phase and amplitude of the returning waves, a computer algorithm reconstructs the image in a holographic format. This reconstruction is not just a simple two-dimensional representation; instead, it captures the intricate details of the object’s surface and internal structure, making it a powerful tool for diagnostics. In the medical field, ultrasonic holography has revolutionized the way we visualize organs and tissues. For instance, it allows for real-time imaging of the heart, providing cardiologists with critical information about heart function without the need for invasive procedures. Furthermore, this technique can be instrumental in detecting tumors or abnormalities within soft tissues, enhancing early diagnosis and treatment planning. The ability to visualize these structures in three dimensions offers a significant advantage over traditional imaging methods, which may only provide flat, two-dimensional images. Beyond medicine, ultrasonic holography plays a crucial role in industrial applications as well. Engineers use this technology to inspect components for flaws or defects during the manufacturing process. By providing a detailed view of the internal and external features of materials, it helps ensure quality control and enhances safety in products ranging from aerospace components to automotive parts. The non-destructive nature of this technique means that valuable materials can be evaluated without causing any damage, preserving their integrity while ensuring they meet safety standards. Moreover, research in ultrasonic holography continues to evolve, with scientists exploring new algorithms and sensors to improve image resolution and processing speed. Innovations in this field could lead to even more applications, such as in the development of smart materials that respond to their environment or in the monitoring of structural health in civil engineering projects. The potential for real-time monitoring of large structures, like bridges or buildings, could significantly enhance public safety and maintenance strategies. In conclusion, ultrasonic holography represents a fusion of technology and creativity, offering unparalleled insights into the physical world. Its applications span multiple disciplines, demonstrating its versatility and importance in both scientific research and practical applications. As advancements continue to emerge, the future of ultrasonic holography looks promising, paving the way for breakthroughs that could transform how we see and understand the world around us.

在先进成像技术的领域中，超声全息术作为一种显著的创新脱颖而出，它结合了超声波和全息术的原理，以创建物体和结构的详细图像。这项技术利用高频声波捕捉物体的三维特征，允许进行非侵入性检查，这在医学、工程和材料科学等多个领域都是无价之宝。超声全息术的本质在于其能够生成全息表示，这提供了深度信息并增强了对复杂形状和内部特征的可视化。该过程始于向目标物体发射超声波。这些波与物体相互作用，反射回传感器，数据在此处被收集。通过分析返回波的相位和幅度，计算机算法重建以全息格式呈现的图像。这种重建不仅仅是简单的二维表示；相反，它捕捉了物体表面和内部结构的复杂细节，使其成为诊断的强大工具。在医学领域，超声全息术彻底改变了我们可视化器官和组织的方式。例如，它允许对心脏进行实时成像，为心脏病专家提供关于心脏功能的重要信息，而无需进行侵入性程序。此外，这项技术对于检测肿瘤或软组织中的异常也非常重要，增强了早期诊断和治疗计划的制定。能够以三维方式可视化这些结构相较于传统成像方法（可能仅提供平面二维图像）具有显著优势。除了医学，超声全息术在工业应用中也发挥着至关重要的作用。工程师利用这项技术在制造过程中检查组件的缺陷或瑕疵。通过提供材料内部和外部特征的详细视图，它有助于确保质量控制，提高从航空航天组件到汽车零件等产品的安全性。这项技术的非破坏性特征意味着可以在不造成任何损害的情况下评估有价值的材料，从而保持其完整性，同时确保它们符合安全标准。此外，超声全息术的研究仍在不断发展，科学家们正在探索新的算法和传感器，以提高图像分辨率和处理速度。该领域的创新可能会导致更多的应用，例如开发对环境做出反应的智能材料，或在土木工程项目中监测结构健康。对大型结构（如桥梁或建筑物）进行实时监测的潜力可能显著增强公共安全和维护策略。总之，超声全息术代表了技术与创造力的融合，提供了对物质世界无与伦比的洞察。它的应用跨越多个学科，展示了其多功能性和在科学研究及实际应用中的重要性。随着不断涌现的进展，超声全息术的未来看起来前景广阔，为可能改变我们观察和理解周围世界的突破铺平了道路。