backlimb thrust
简明释义
1. 后翼冲断层; 2. 缓翼冲断层;
英英释义
例句
1.In gymnastics, mastering the backlimb thrust is crucial for performing complex routines.
在体操中,掌握后肢推力对执行复杂的动作至关重要。
2.During the sprint, the runner relied on a strong backlimb thrust to propel forward.
在短跑过程中,跑者依靠强大的后肢推力向前推进。
3.The athlete executed a perfect jump using the backlimb thrust to gain height.
运动员通过使用后肢推力完美地完成了跳跃,以获得高度。
4.To achieve maximum distance in the long jump, athletes must optimize their backlimb thrust.
为了在跳远中达到最大距离,运动员必须优化他们的后肢推力。
5.The coach emphasized the importance of the backlimb thrust in improving overall performance.
教练强调了后肢推力在提高整体表现中的重要性。
作文
In the realm of biomechanics and animal locomotion, understanding the mechanics behind movement is crucial. One fascinating aspect of this study is the concept of backlimb thrust, which refers to the force generated by the hind limbs of an animal during locomotion. This thrust plays a significant role in how various species move, whether they are running, jumping, or swimming. The efficiency of backlimb thrust can determine an animal's speed, agility, and overall performance in its environment.To illustrate this further, let’s consider the example of a cheetah, known for being the fastest land animal. The cheetah's ability to reach speeds of up to 75 miles per hour is largely attributed to its powerful backlimb thrust. As it sprints, the hind legs push against the ground with tremendous force, propelling the body forward. The coordination between the back limbs and the front limbs is essential for maintaining balance and maximizing speed. In essence, the effectiveness of backlimb thrust allows the cheetah to accelerate rapidly and make sharp turns, which are vital for catching prey in the wild.Similarly, in the world of aquatic animals, fish utilize backlimb thrust in a different manner. Although fish do not have limbs as terrestrial animals do, their tail fins serve a comparable function. The powerful strokes of a fish's tail create thrust that propels it through the water. This movement is critical for swimming efficiently and escaping predators. The design and structure of the tail fin influence the amount of backlimb thrust generated, showcasing the diversity of adaptations across species.In addition to understanding animal movement, the concept of backlimb thrust has applications in robotics and engineering. Engineers often look to nature for inspiration when designing robots that mimic animal locomotion. By studying how animals generate thrust with their limbs, engineers can create more efficient robotic systems. For instance, a robot designed to traverse rough terrain might incorporate mechanisms that replicate the backlimb thrust of a kangaroo, allowing it to hop over obstacles with ease.Moreover, the study of backlimb thrust extends into the field of rehabilitation and physical therapy. Understanding the mechanics of how humans and animals use their back limbs can help therapists develop better recovery programs for individuals with mobility issues. By focusing on exercises that enhance backlimb thrust, patients can improve their strength and coordination, leading to better outcomes in their rehabilitation process.In conclusion, the concept of backlimb thrust is a vital component of biomechanics that influences how animals and even robots move. From the explosive speed of a cheetah to the graceful swimming of a fish, the thrust generated by hind limbs is essential for effective locomotion. Furthermore, this understanding not only enriches our knowledge of animal behavior but also inspires innovations in technology and aids in human rehabilitation. As we continue to explore the intricacies of movement, the significance of backlimb thrust will undoubtedly remain a focal point in both scientific research and practical applications.
在生物力学和动物运动的领域,理解运动背后的机制至关重要。一个引人入胜的方面是“后肢推力”的概念,它指的是动物在运动过程中后肢产生的力量。这种推力在各种物种的移动中发挥着重要作用,无论是奔跑、跳跃还是游泳。“后肢推力”的效率可以决定动物在其环境中的速度、敏捷性和整体表现。为了进一步说明这一点,让我们考虑猎豹的例子,它被认为是最快的陆地动物。猎豹能够达到每小时75英里的速度,主要归功于其强大的“后肢推力”。在疾驰时,后腿以巨大的力量向地面发力,推动身体向前。后肢与前肢之间的协调对于保持平衡和最大化速度至关重要。本质上,“后肢推力”的有效性使猎豹能够迅速加速并做出急转弯,这对捕捉野生猎物至关重要。同样,在水生动物的世界中,鱼类以不同的方式利用“后肢推力”。虽然鱼没有像陆生动物那样的肢体,但它们的尾鳍起着相似的作用。鱼的尾巴有力的摆动产生了推动力,使其在水中推进。这种运动对于高效游泳和逃避捕食者至关重要。尾鳍的设计和结构影响着产生的“后肢推力”的数量,展示了物种之间适应性的多样性。除了理解动物运动外,“后肢推力”的概念在机器人和工程领域也有应用。工程师们常常从自然界中寻找灵感,以设计模仿动物运动的机器人。通过研究动物如何用肢体产生推力,工程师们可以创造出更高效的机器人系统。例如,一种设计用于穿越崎岖地形的机器人可能会结合复制袋鼠“后肢推力”的机制,使其能够轻松跳过障碍物。此外,“后肢推力”的研究扩展到康复和物理治疗领域。理解人类和动物如何使用后肢的机械原理可以帮助治疗师制定更好的恢复计划,以应对行动能力受限的人群。通过专注于增强“后肢推力”的锻炼,患者可以改善他们的力量和协调性,从而在康复过程中取得更好的结果。总之,“后肢推力”的概念是生物力学中一个至关重要的组成部分,影响着动物甚至机器人的运动。从猎豹的爆发性速度到鱼的优雅游动,后肢产生的推力对于有效的运动至关重要。此外,这种理解不仅丰富了我们对动物行为的认识,还激发了技术创新,并有助于人类康复。随着我们继续探索运动的复杂性,“后肢推力”的重要性无疑将继续成为科学研究和实际应用的焦点。
