omnidirectional measurement

简明释义

全向测量

英英释义

例句

1.In robotics, omnidirectional measurement is crucial for accurately mapping the environment.

在机器人技术中，全向测量对于准确绘制环境至关重要。

2.With omnidirectional measurement, we can analyze the light distribution in a room more effectively.

通过全向测量，我们可以更有效地分析房间内的光分布。

3.The new sound system features omnidirectional measurement to capture audio from all directions.

新音响系统具有全向测量功能，可以从各个方向捕捉音频。

4.The research team implemented omnidirectional measurement techniques to study the effects of sound on human behavior.

研究小组实施了全向测量技术，以研究声音对人类行为的影响。

5.The engineers used omnidirectional measurement to ensure the antenna could receive signals from any angle.

工程师们使用全向测量来确保天线能够从任何角度接收信号。

作文

In the realm of technology and engineering, the concept of omnidirectional measurement plays a crucial role in various applications. This term refers to the ability to capture data from all directions equally, providing a comprehensive understanding of the environment or subject being analyzed. Unlike traditional measurement techniques that may focus on a single direction or a limited range, omnidirectional measurement allows for a more holistic view, which is particularly beneficial in fields such as robotics, telecommunications, and environmental monitoring.For instance, in the field of robotics, robots equipped with omnidirectional measurement sensors can navigate complex environments more effectively. These sensors collect data about obstacles, terrain, and other important factors from every angle, enabling the robot to make informed decisions in real-time. This capability is essential for autonomous vehicles, which must constantly assess their surroundings to avoid collisions and navigate safely.Similarly, in telecommunications, omnidirectional measurement is vital for optimizing signal strength and quality. Antennas designed for omnidirectional measurement can receive and transmit signals from all directions, ensuring that communication is maintained even in challenging environments. This is particularly important in urban areas where buildings and other structures can obstruct signals, leading to dead zones. By utilizing omnidirectional measurement, engineers can design networks that provide consistent coverage and improved user experiences.Environmental monitoring also greatly benefits from omnidirectional measurement. Sensors deployed in natural habitats can gather data on temperature, humidity, air quality, and other environmental factors from multiple directions. This comprehensive data collection helps scientists understand ecological changes, track wildlife movements, and assess the impact of human activities on the environment. For example, a weather station employing omnidirectional measurement can provide a more accurate representation of local weather patterns by capturing data from various angles rather than relying on a single point of measurement.Moreover, the advancements in technology have enabled the development of sophisticated tools that utilize omnidirectional measurement. Devices like 360-degree cameras and LiDAR systems are examples of technologies that leverage this concept. These devices can create detailed representations of their surroundings, allowing for applications in virtual reality, urban planning, and even disaster response. By providing a complete view of an area, omnidirectional measurement enhances decision-making processes and facilitates better planning and management.In conclusion, omnidirectional measurement is a powerful concept that enhances our ability to analyze and interact with the world around us. Its applications span various fields, including robotics, telecommunications, and environmental science, proving its versatility and importance. As technology continues to advance, the significance of omnidirectional measurement will only grow, paving the way for innovations that improve our daily lives and contribute to a deeper understanding of complex systems. Embracing this concept will undoubtedly lead to more effective solutions and a brighter future across multiple disciplines.

在技术和工程领域，全向测量的概念在各种应用中起着至关重要的作用。这个术语指的是能够从所有方向均匀捕获数据，从而对正在分析的环境或主题提供全面理解的能力。与传统的测量技术不同，后者可能专注于单一方向或有限范围，全向测量允许更全面的视角，这在机器人技术、电信和环境监测等领域尤其有益。例如，在机器人领域，配备有全向测量传感器的机器人可以更有效地导航复杂环境。这些传感器从各个角度收集关于障碍物、地形和其他重要因素的数据，使机器人能够实时做出明智的决策。这种能力对于自主车辆至关重要，因为它们必须不断评估周围环境以避免碰撞并安全导航。同样，在电信领域，全向测量对于优化信号强度和质量至关重要。设计用于全向测量的天线能够从所有方向接收和发送信号，确保即使在挑战性环境中也能保持通信。这在城市地区尤其重要，因为建筑物和其他结构可能会阻碍信号，导致死区。通过利用全向测量，工程师可以设计出提供一致覆盖和改善用户体验的网络。环境监测也极大地受益于全向测量。部署在自然栖息地中的传感器可以从多个方向收集温度、湿度、空气质量和其他环境因素的数据。这种全面的数据收集帮助科学家理解生态变化、追踪野生动物运动，并评估人类活动对环境的影响。例如，使用全向测量的气象站可以通过捕获来自不同角度的数据来提供对当地天气模式的更准确表示，而不是依赖于单一点的测量。此外，技术的进步使得利用全向测量开发复杂工具成为可能。360度相机和激光雷达系统就是利用这一概念的技术示例。这些设备能够创建其周围环境的详细表示，允许在虚拟现实、城市规划甚至灾难响应等应用中使用。通过提供区域的完整视图，全向测量增强了决策过程，并促进了更好的规划和管理。总之，全向测量是一个强大的概念，增强了我们分析和与周围世界互动的能力。它的应用跨越多个领域，包括机器人技术、电信和环境科学，证明了它的多功能性和重要性。随着技术的不断进步，全向测量的重要性只会增加，为改善我们日常生活和深入理解复杂系统铺平道路。接受这一概念无疑会导致更有效的解决方案，并在多个学科中为更加光明的未来做出贡献。