locomotory
简明释义
英[ˌləʊkəˈməʊtəri]美[loʊkəˈmoʊtəri]
adj. 运动的;移动的(等于 locomotor)
英英释义
与运动或移动有关的。 |
单词用法
运动功能 | |
运动系统 | |
运动器官 | |
运动行为 |
同义词
| 运动的 | 运动技能对身体活动至关重要 | ||
| 可移动的 | 这个移动应用程序使用户能够轻松导航 | ||
| 机动的 | 机车设计在交通运输中具有革命性 |
反义词
| 静止的 | 在交通堵塞中,汽车保持静止。 | ||
| 不动的 | 事故后,他几周都无法动弹。 |
例句
1.These fossils represent different major groups and show high diversity in body size, locomotory adaptation, and dietary.
这些化石代表了不同的哺乳动物大类,同时显示了在个体大小、运动姿态以及食性方面的较高的分异。
2.Objective it is to discuss the relationship of locomotory capacity with respiration drive, air way resistance and lactic acid in the patients with chronic obstructive pulmonary disease (COPD).
目的探讨慢性阻塞性肺疾病(COPD)患者运动能力与呼吸驱动、气道阻力和乳酸的关系。
3.Objective to investigate the influence of home rehabilitation nursing intervention on locomotory capacity and activities of daily living with brain stroke patients.
目的探讨家庭护理干预对脑卒中患者运动能力及日常生活活动能力的影响。
4.To realize the undulatory control of the flexible fin, a locomotory model is analyzed and a distributed control structure is designed.
针对柔性长鳍特有的 波动控制问题,本文分析了柔性长鳍的运动模型,并设计了一种分布式控制系统结构。
5.Objective it is to discuss the relationship of locomotory capacity with respiration drive, air way resistance and lactic acid in the patients with chronic obstructive pulmonary disease (COPD).
目的探讨慢性阻塞性肺疾病(COPD)患者运动能力与呼吸驱动、气道阻力和乳酸的关系。
6.Children often exhibit a range of locomotory 运动的 activities during playtime, which is crucial for their development.
孩子们在玩耍时常常表现出一系列的locomotory 运动的 活动,这对他们的发展至关重要。
7.The study focused on the locomotory 运动的 abilities of various animal species in their natural habitats.
这项研究集中于各种动物在其自然栖息地中的locomotory 运动的 能力。
8.The robot was designed with advanced locomotory 运动的 functions to navigate uneven terrains.
该机器人设计了先进的locomotory 运动的 功能,以便在不平坦的地形上导航。
9.The researchers observed the locomotory 运动的 patterns of fish in response to environmental changes.
研究人员观察了鱼类对环境变化的locomotory 运动的 模式。
10.In rehabilitation, improving a patient’s locomotory 运动的 skills is essential for their recovery.
在康复中,提高患者的locomotory 运动的 技能对他们的恢复至关重要。
作文
The study of animal behavior often leads us to explore various aspects of their biology, including their movement patterns. One fascinating aspect of this is the concept of locomotory 运动的 abilities in different species. Understanding how animals move not only sheds light on their survival strategies but also informs us about their evolutionary adaptations. For instance, consider the graceful movements of a cheetah. Its locomotory 运动的 skills are finely tuned for speed, allowing it to sprint at incredible velocities to catch prey. This adaptation showcases the importance of efficient movement in the animal kingdom. In contrast, aquatic animals like fish exhibit a different set of locomotory 运动的 adaptations. Their streamlined bodies and fins allow them to glide effortlessly through water, demonstrating how environmental factors influence movement. The study of these locomotory 运动的 adaptations can provide insights into the ecological niches that different species occupy. Birds, too, present a unique perspective on locomotory 运动的 evolution. Their ability to fly has led to a myriad of adaptations, from wing shape to body size. The mechanics of avian flight are a prime example of how locomotory 运动的 capabilities can evolve in response to environmental pressures. Each species has developed specific traits that enhance their mobility, whether it be for escaping predators or foraging for food. Furthermore, the study of locomotory 运动的 mechanisms extends beyond just animals; it also includes human movement. In biomechanics, researchers analyze how humans walk, run, and perform various physical activities. Understanding our own locomotory 运动的 patterns can lead to advancements in rehabilitation and sports science. For example, athletes often work with trainers to improve their locomotory 运动的 efficiency, which can enhance performance and reduce the risk of injury. Moreover, the impact of technology on locomotory 运动的 abilities cannot be overlooked. With the advent of robotics and artificial intelligence, researchers are developing machines that mimic the locomotory 运动的 functions of living organisms. These innovations have potential applications in various fields, from medicine to exploration. In conclusion, the study of locomotory 运动的 abilities across different species reveals a wealth of information about adaptation and survival. Whether in the animal kingdom or in human biomechanics, understanding movement is crucial for comprehending the complexities of life. As we continue to explore the intricacies of locomotory 运动的 systems, we gain a deeper appreciation for the diverse strategies that organisms employ to navigate their environments.
动物行为的研究常常引导我们探索它们生物学的各个方面,包括它们的运动模式。一个令人着迷的方面是不同物种的locomotory 运动的能力。理解动物如何移动不仅能揭示它们的生存策略,还能让我们了解它们的进化适应。例如,考虑一下猎豹优雅的动作。它的locomotory 运动的技能经过精细调校,能够以惊人的速度冲刺捕捉猎物。这种适应展示了高效运动在动物王国中的重要性。相比之下,水生动物如鱼类则表现出一套不同的locomotory 运动的适应。它们流线型的身体和鳍使它们能够轻松地在水中滑行,展示了环境因素如何影响运动。对这些locomotory 运动的适应的研究可以提供关于不同物种所占生态位的见解。鸟类也为locomotory 运动的进化提供了独特的视角。它们飞行的能力导致了无数的适应,从翅膀形状到体型。鸟类飞行的力学是locomotory 运动的能力如何响应环境压力进化的一个典范。每个物种都发展出了增强其移动性的特定特征,无论是为了逃避捕食者还是觅食。此外,locomotory 运动的机制的研究不仅限于动物;它还包括人类运动。在生物力学中,研究人员分析人类如何走路、跑步以及进行各种体育活动。理解我们自己的locomotory 运动的模式可以促进康复和运动科学的进步。例如,运动员通常与教练合作以提高他们的locomotory 运动的效率,这可以增强表现并降低受伤风险。此外,技术对locomotory 运动的能力的影响也不容忽视。随着机器人技术和人工智能的出现,研究人员正在开发模拟生物体locomotory 运动的功能的机器。这些创新在医学和探索等多个领域具有潜在应用。总之,研究不同物种的locomotory 运动的能力揭示了关于适应和生存的丰富信息。无论是在动物王国还是在人类生物力学中,理解运动对于理解生命的复杂性至关重要。随着我们继续探索locomotory 运动的系统的复杂性,我们对有机体在其环境中导航所采用的多样化策略有了更深刻的欣赏。
