jaw rate control

简明释义

船首摇摆率的控制

英英释义

例句

1.During the orthodontic treatment, the doctor emphasized the need for jaw rate control to ensure proper alignment of the teeth.

在正畸治疗期间，医生强调了需要下颌速率控制以确保牙齿的正确排列。

2.In speech therapy, jaw rate control is crucial for improving articulation and clarity.

在语言治疗中，下颌速率控制对改善发音和清晰度至关重要。

3.The physical therapist recommended exercises focused on jaw rate control to alleviate tension headaches.

物理治疗师推荐专注于下颌速率控制的锻炼，以缓解紧张性头痛。

4.The dentist explained the importance of jaw rate control in preventing excessive strain on the jaw muscles.

牙医解释了下颌速率控制在防止下颌肌肉过度紧张中的重要性。

5.Athletes are often advised to practice jaw rate control to enhance their performance during competitions.

运动员通常被建议练习下颌速率控制以提高他们在比赛中的表现。

作文

In the field of robotics and artificial intelligence, precise control over mechanical movements is crucial for achieving desired outcomes. One such concept that plays a vital role in this area is jaw rate control. This term refers to the regulation of the speed at which a robotic jaw or gripper operates. Understanding jaw rate control is essential for enhancing the functionality and efficiency of robotic systems, particularly in applications involving delicate tasks such as assembly, surgery, or even culinary processes.To begin with, let us explore the significance of jaw rate control in robotics. When robots are designed to interact with their environment, they must perform tasks that require varying levels of precision and speed. For example, a robotic arm used in a manufacturing line may need to pick up fragile components without causing damage. In such scenarios, the ability to control the rate at which the jaw opens and closes becomes paramount. If the jaw moves too quickly, it may crush the object; if it moves too slowly, it may not complete the task efficiently.Moreover, jaw rate control is not only about speed but also about synchronization. In complex robotic systems where multiple joints and components must work together, ensuring that the jaw's movement is coordinated with other parts of the robot is essential. This synchronization can prevent mechanical failures and enhance the overall reliability of the robotic system.Another important aspect of jaw rate control is its impact on user experience. In applications such as telepresence robots or assistive technologies, where human operators control the robot remotely, the responsiveness of the jaw movement can significantly affect how effectively the operator can perform tasks. A well-tuned jaw rate control system allows for smoother and more intuitive interactions, thereby improving the overall effectiveness of the technology.Additionally, advancements in sensor technology have greatly contributed to the development of sophisticated jaw rate control mechanisms. Modern robots often utilize feedback systems that monitor the position and speed of the jaw in real-time. By integrating sensors that detect force, pressure, and even the texture of objects, robots can adjust their jaw movements dynamically to suit the specific requirements of a task. This level of adaptability is what sets advanced robotic systems apart from their simpler counterparts.Furthermore, the implications of jaw rate control extend beyond industrial applications. In healthcare, for instance, surgical robots rely heavily on precise jaw movements to perform intricate procedures. The ability to finely tune the jaw rate can mean the difference between a successful operation and a complication. Surgeons can benefit from enhanced control, allowing them to execute delicate maneuvers with confidence.In conclusion, jaw rate control is a fundamental concept in the realm of robotics that encompasses the regulation of jaw movement speed and synchronization. Its importance cannot be overstated, as it influences the efficiency, reliability, and user experience of robotic systems across various industries. As technology continues to advance, the refinement of jaw rate control will undoubtedly lead to even more innovative applications and improvements in robotic capabilities. Understanding and mastering this concept is essential for anyone looking to delve into the exciting world of robotics and automation.

在机器人和人工智能领域，对机械运动的精确控制对于实现预期结果至关重要。其中一个在这一领域扮演着重要角色的概念是下颌速率控制。这个术语指的是对机器人下颌或抓手操作速度的调节。理解下颌速率控制对提高机器人系统的功能和效率至关重要，尤其是在涉及精细任务的应用中，如组装、手术甚至烹饪过程。首先，让我们探讨一下下颌速率控制在机器人技术中的重要性。当机器人被设计用来与环境互动时，它们必须执行需要不同精度和速度水平的任务。例如，用于制造生产线的机器人手臂可能需要捡起脆弱的组件而不造成损坏。在这种情况下，控制下颌开合速度的能力变得至关重要。如果下颌移动得太快，可能会压碎物体；如果移动得太慢，则可能无法高效完成任务。此外，下颌速率控制不仅仅关乎速度，还关乎同步。在复杂的机器人系统中，多个关节和组件必须协同工作，确保下颌的运动与机器人的其他部分协调一致至关重要。这种同步可以防止机械故障，并增强机器人系统的整体可靠性。下颌速率控制的另一个重要方面是其对用户体验的影响。在远程控制的存在机器人或辅助技术等应用中，人类操作员远程控制机器人，掌握下颌运动的响应能力会显著影响操作员执行任务的有效性。良好调校的下颌速率控制系统允许更平滑和更直观的交互，从而提高技术的整体有效性。此外，传感器技术的进步极大地促进了复杂的下颌速率控制机制的发展。现代机器人通常利用反馈系统实时监控下颌的位置和速度。通过集成检测力、压力甚至物体纹理的传感器，机器人可以动态调整其下颌运动，以适应特定任务的要求。这种适应能力正是先进机器人系统与简单机器人系统之间的区别所在。此外，下颌速率控制的影响超越了工业应用。在医疗保健中，例如，外科手术机器人在执行复杂手术时严重依赖精确的下颌运动。微调下颌速率的能力可能意味着成功手术与并发症之间的区别。外科医生可以从增强的控制中受益，使他们能够自信地执行精细操作。总之，下颌速率控制是机器人领域的一个基本概念，涵盖了下颌运动速度和同步性的调节。它的重要性不容小觑，因为它影响着各行业机器人系统的效率、可靠性和用户体验。随着技术的不断进步，下颌速率控制的完善无疑将导致更具创新性的应用和机器人能力的提升。理解和掌握这一概念对于任何希望深入探索机器人和自动化激动人心世界的人来说都是至关重要的。