autonomic movement

简明释义

自发运动

英英释义

例句

1.The drone's autonomic movement capabilities enable it to fly and avoid obstacles automatically.

这架无人机的自主运动能力使其能够自动飞行并避开障碍物。

2.In the study of biology, autonomic movement refers to the actions that occur without conscious control, such as reflexes.

在生物学研究中，自主运动指的是那些在没有意识控制下发生的动作，例如反射。

3.The robot was designed to perform tasks through autonomic movement, allowing it to navigate its environment without human intervention.

这款机器人被设计为通过自主运动执行任务，使其能够在没有人类干预的情况下导航其环境。

4.Researchers are exploring how autonomic movement in animals can inspire new robotic designs.

研究人员正在探索动物中的自主运动如何启发新的机器人设计。

5.The self-driving car utilizes autonomic movement to adjust its speed and direction based on real-time traffic data.

这辆自动驾驶汽车利用自主运动根据实时交通数据调整其速度和方向。

作文

In the realm of biology and neuroscience, the term autonomic movement refers to actions that occur without conscious thought or effort. These movements are often governed by the autonomic nervous system, which regulates involuntary bodily functions such as heart rate, digestion, and respiratory rate. Understanding autonomic movement is crucial for grasping how our bodies operate on a fundamental level, especially in response to external stimuli.For instance, when we touch something hot, the immediate reaction is often a withdrawal of the hand. This reflexive action is an example of autonomic movement, as it happens automatically and does not require deliberate thought. The sensory nerves send signals to the spinal cord, which then relays a response back to the muscles, causing them to contract and pull away from the source of pain. This process highlights the efficiency and speed of autonomic movement, which is essential for survival.Moreover, autonomic movement can also be observed in various biological systems beyond human physiology. For example, many animals exhibit instinctual behaviors that are driven by their autonomic responses. Birds migrating south for the winter, for instance, do so based on environmental cues and internal biological clocks, demonstrating how autonomic movement plays a pivotal role in the life cycles of various species.In addition to its biological significance, the concept of autonomic movement has implications in the field of robotics and artificial intelligence. Engineers and researchers strive to create machines and systems that can mimic these natural, instinctual movements. By studying how living organisms respond autonomously to their environments, they can design robots that react swiftly and appropriately to changing conditions. This pursuit not only enhances the functionality of robotic systems but also contributes to advancements in automation technology, making machines more efficient and capable of performing tasks that require quick decision-making.Furthermore, understanding autonomic movement can aid in medical research and treatment. For instance, disorders that affect the autonomic nervous system can lead to a variety of health issues, including heart problems and digestive disorders. By focusing on the mechanisms behind autonomic movement, scientists can develop targeted therapies to help manage these conditions, improving patients' quality of life.In conclusion, the study of autonomic movement encompasses a wide range of disciplines, from biology and neuroscience to robotics and medicine. Recognizing the importance of these involuntary actions helps us appreciate the complexity of living organisms and the intricate systems that govern our behaviors and responses. As we continue to explore the depths of autonomic movement, we unlock new possibilities for innovation and healing, bridging the gap between nature and technology. The future holds great promise as we delve deeper into this fascinating area of study, ultimately enhancing our understanding of both ourselves and the world around us.

在生物学和神经科学领域，术语自主运动指的是在没有意识思考或努力的情况下发生的动作。这些运动通常由自主神经系统控制，该系统调节心率、消化和呼吸速率等非自愿身体功能。理解自主运动对于掌握我们身体如何在基本层面上运作至关重要，特别是在响应外部刺激时。例如，当我们触摸到热物体时，立即的反应往往是撤回手。这种反射动作是自主运动的一个例子，因为它是自动发生的，不需要深思熟虑。感觉神经将信号发送到脊髓，然后再将反应传回肌肉，导致它们收缩并远离痛苦的来源。这个过程突显了自主运动的效率和速度，这对生存至关重要。此外，自主运动也可以在各种生物系统中观察到，超越人类生理学。例如，许多动物表现出由其自主反应驱动的本能行为。例如，鸟类在冬季向南迁徙，正是基于环境线索和内部生物钟，展示了自主运动在各种物种生命周期中的关键作用。除了其生物学意义外，自主运动的概念在机器人和人工智能领域也具有重要意义。工程师和研究人员努力创造能够模仿这些自然本能运动的机器和系统。通过研究生物体如何自主地响应其环境，他们可以设计出能迅速且适当地对变化条件做出反应的机器人。这一追求不仅提高了机器人系统的功能性，还促进了自动化技术的进步，使机器更高效，能够执行需要快速决策的任务。此外，了解自主运动可以帮助医学研究和治疗。例如，影响自主神经系统的疾病可能导致各种健康问题，包括心脏病和消化障碍。通过关注自主运动背后的机制，科学家可以开发出针对性的疗法来帮助管理这些情况，提高患者的生活质量。总之，自主运动的研究涵盖了广泛的学科，从生物学和神经科学到机器人技术和医学。认识到这些非自愿动作的重要性帮助我们欣赏生物体的复杂性以及支配我们行为和反应的精密系统。随着我们继续探索自主运动的深度，我们解锁了创新和治疗的新可能性，架起了自然与技术之间的桥梁。未来充满希望，因为我们深入研究这一迷人的领域，最终增强我们对自己和周围世界的理解。