back cscillation

简明释义

回波振荡;

英英释义

例句

1.In robotics, back cscillation 反向振荡 can affect the precision of movements.

在机器人技术中，反向振荡可能会影响运动的精确性。

2.The sound waves created a noticeable back cscillation 反向振荡 in the room, making it difficult to hear the speaker.

声音波在房间内产生了明显的反向振荡，使得听演讲者变得困难。

3.The engineers had to account for back cscillation 反向振荡 when designing the new bridge.

工程师在设计新桥时必须考虑到反向振荡。

4.During the experiment, the back cscillation 反向振荡 of the pendulum was recorded for analysis.

在实验过程中，摆的反向振荡被记录下来以供分析。

5.The musician adjusted the settings to minimize back cscillation 反向振荡 during the live performance.

音乐家调整设置以最小化现场表演中的反向振荡。

作文

In the realm of physics and engineering, the concept of back cscillation plays a crucial role in understanding various dynamic systems. Back cscillation refers to the phenomenon where a system oscillates back and forth around an equilibrium point, often influenced by external forces or internal feedback mechanisms. This behavior can be observed in numerous applications, from mechanical systems to electrical circuits, and even in biological processes. To illustrate this concept further, let’s consider the example of a pendulum. When a pendulum is displaced from its resting position and then released, it swings back and forth due to the force of gravity acting upon it. This swinging motion is a classic example of back cscillation, where the pendulum oscillates around its equilibrium position. The amplitude of the oscillation may decrease over time due to friction and air resistance, demonstrating how energy dissipation affects the system's behavior.In engineering, understanding back cscillation is vital for designing stable control systems. For instance, in robotics, a robot arm must accurately position itself without overshooting or oscillating excessively. Engineers often utilize feedback control mechanisms to dampen any back cscillation that may occur during the movement of the robotic arm. By carefully tuning the control parameters, they can achieve a smooth and precise operation, minimizing the risk of mechanical failure or inefficiency. Moreover, back cscillation is not limited to mechanical systems. In electrical engineering, oscillators are devices that generate periodic signals. These oscillators can experience back cscillation when they are perturbed by external signals or noise. Designers must account for these oscillations to ensure that the output remains stable and reliable. In the biological sciences, back cscillation can be observed in population dynamics. For example, predator-prey relationships often exhibit oscillatory behavior, where the population of predators and prey oscillates over time. This back cscillation is driven by the interactions between the two species, leading to cycles of growth and decline. Understanding these dynamics is essential for conservation efforts and managing ecosystems effectively.In conclusion, the concept of back cscillation is fundamental across various fields, including physics, engineering, and biology. It describes the oscillatory behavior of systems around an equilibrium point, influenced by both internal and external factors. By comprehensively understanding back cscillation, professionals can design better systems, predict behaviors, and implement effective solutions to complex problems. As we continue to explore and innovate in our respective fields, the principles of back cscillation will undoubtedly remain a key focus for researchers and practitioners alike.

在物理和工程领域，back cscillation的概念在理解各种动态系统中起着至关重要的作用。Back cscillation指的是一个系统围绕平衡点来回振荡的现象，通常受到外部力量或内部反馈机制的影响。这种行为可以在许多应用中观察到，从机械系统到电气电路，甚至在生物过程中。为了进一步说明这一概念，让我们考虑一个摆的例子。当一个摆被从其静止位置偏移并释放时，它由于重力的作用而前后摆动。这种摆动运动是back cscillation的经典例子，其中摆围绕其平衡位置振荡。由于摩擦和空气阻力，振荡的幅度可能会随着时间的推移而减小，这表明能量耗散如何影响系统的行为。在工程学中，理解back cscillation对于设计稳定的控制系统至关重要。例如，在机器人技术中，机器人手臂必须准确地定位，而不出现过冲或过度振荡。工程师们常常利用反馈控制机制来减弱在机器人手臂移动过程中可能发生的任何back cscillation。通过仔细调整控制参数，他们可以实现平滑和精确的操作，最大限度地减少机械故障或低效的风险。此外，back cscillation并不限于机械系统。在电气工程中，振荡器是一种产生周期性信号的设备。当这些振荡器受到外部信号或噪声的扰动时，它们可能会经历back cscillation。设计者必须考虑这些振荡，以确保输出保持稳定和可靠。在生物科学中，back cscillation可以在种群动态中观察到。例如，捕食者与猎物之间的关系往往表现出振荡行为，其中捕食者和猎物的种群随时间波动。这种back cscillation是由两种生物之间的相互作用驱动的，导致增长和衰退的循环。理解这些动态对于保护工作和有效管理生态系统至关重要。总之，back cscillation的概念在物理、工程和生物等各个领域都是基础。它描述了系统围绕平衡点的振荡行为，受到内部和外部因素的影响。通过全面理解back cscillation，专业人员可以设计更好的系统，预测行为，并实施有效的解决方案来应对复杂问题。随着我们在各自领域的不断探索和创新，back cscillation的原理无疑将继续成为研究人员和从业者关注的重点。