angular deviation sensitivity

简明释义

角偏转灵敏度

英英释义

例句

1.The camera calibration process must account for angular deviation sensitivity 角度偏差敏感性 to ensure accurate image capture.

相机校准过程必须考虑角度偏差敏感性 angular deviation sensitivity，以确保图像捕捉的准确性。

2.In virtual reality systems, angular deviation sensitivity 角度偏差敏感性 affects user experience and immersion.

在虚拟现实系统中，角度偏差敏感性 angular deviation sensitivity 影响用户体验和沉浸感。

3.The robot's navigation system is designed to minimize angular deviation sensitivity 角度偏差敏感性 when moving through complex environments.

机器人的导航系统旨在最小化角度偏差敏感性 angular deviation sensitivity，以便在复杂环境中移动。

4.Engineers must evaluate the angular deviation sensitivity 角度偏差敏感性 of sensors in robotic arms to improve precision.

工程师必须评估机器人手臂传感器的角度偏差敏感性 angular deviation sensitivity，以提高精度。

5.In aerospace engineering, angular deviation sensitivity 角度偏差敏感性 is crucial for maintaining flight stability during maneuvers.

在航空航天工程中，角度偏差敏感性 angular deviation sensitivity 对于在机动过程中保持飞行稳定性至关重要。

作文

In the field of optics and engineering, the concept of angular deviation sensitivity plays a crucial role in understanding how systems respond to changes in angle. This term refers to the degree to which a system's output or performance is affected by variations in the angle of input. For example, in optical devices such as cameras and telescopes, even a slight change in the angle of light can lead to significant differences in image quality. Therefore, engineers must carefully design these systems to minimize the angular deviation sensitivity to ensure that they perform optimally under various conditions.The importance of angular deviation sensitivity extends beyond optics into various fields, including robotics, navigation, and telecommunications. In robotics, for instance, the precision of movement is often reliant on the robot's ability to detect and adjust for angular deviations. A robot that is highly sensitive to angular changes can navigate complex environments more effectively, making it essential in applications such as autonomous vehicles and drones.Moreover, in navigation systems, particularly those relying on gyroscopes and accelerometers, angular deviation sensitivity is critical for accuracy. These systems must account for any angular deviation to provide precise location data. If the sensitivity is too high, even minor disturbances can lead to significant errors, compromising the entire navigation process. This highlights the need for a balanced approach where sensitivity is tuned to achieve optimal performance without introducing excessive noise or error.Telecommunications also benefit from understanding angular deviation sensitivity. Signal transmission can be affected by angular misalignments in antennas or satellite dishes. Engineers must design these components with low angular deviation sensitivity to ensure that signals remain strong and clear despite minor adjustments in angle. This is particularly important in mobile communications, where users frequently change positions and orientations.To sum up, angular deviation sensitivity is a fundamental concept that influences the design and functionality of many modern technologies. By understanding and controlling this sensitivity, engineers can create more reliable and efficient systems across various domains. As technology continues to advance, the need for precise control over angular deviation sensitivity will only grow, making it an area of ongoing research and development. Ultimately, mastering this concept is essential for anyone involved in the fields of optics, robotics, navigation, and telecommunications, as it directly impacts the effectiveness and performance of their designs and solutions.

在光学和工程领域，角度偏差灵敏度的概念在理解系统如何响应角度变化方面起着至关重要的作用。这个术语指的是系统的输出或性能受到输入角度变化影响的程度。例如，在相机和望远镜等光学设备中，即使是微小的光线角度变化也会导致图像质量的显著差异。因此，工程师必须仔细设计这些系统，以最小化角度偏差灵敏度，以确保它们在各种条件下表现最佳。角度偏差灵敏度的重要性不仅限于光学，还扩展到机器人技术、导航和电信等多个领域。例如，在机器人技术中，运动的精确性往往依赖于机器人检测和调整角度偏差的能力。对角度变化高度敏感的机器人可以更有效地在复杂环境中导航，这在自动驾驶汽车和无人机等应用中至关重要。此外，在导航系统中，特别是依赖于陀螺仪和加速度计的系统，角度偏差灵敏度对于准确性至关重要。这些系统必须考虑任何角度偏差，以提供精确的位置数据。如果灵敏度过高，即使是轻微的干扰也可能导致显著的错误，从而损害整个导航过程。这突显了需要一种平衡的方法，即灵敏度调节到实现最佳性能，而不引入过多的噪声或错误。电信也受益于对角度偏差灵敏度的理解。信号传输可能会受到天线或卫星天线的角度失调的影响。工程师必须设计这些组件，使其具有较低的角度偏差灵敏度，以确保信号在角度发生微小调整时仍然保持强大和清晰。这在移动通信中特别重要，因为用户经常改变位置和方向。总之，角度偏差灵敏度是一个影响许多现代技术设计和功能的基本概念。通过理解和控制这种灵敏度，工程师可以在各个领域创造出更可靠和高效的系统。随着技术的不断进步，对角度偏差灵敏度的精确控制的需求只会增加，这使其成为一个持续研究和发展的领域。最终，掌握这个概念对于任何参与光学、机器人技术、导航和电信领域的人来说都是至关重要的，因为它直接影响到他们设计和解决方案的有效性和性能。