balanced oscillator

简明释义

平衡振荡器

英英释义

例句

1.In electronics, a balanced oscillator 平衡振荡器 is used to generate stable frequencies for communication systems.

在电子学中，平衡振荡器 balanced oscillator 用于为通信系统生成稳定的频率。

2.Engineers often use a balanced oscillator 平衡振荡器 in phase-locked loops to maintain signal integrity.

工程师常在锁相环中使用平衡振荡器 balanced oscillator 以保持信号完整性。

3.The design of a balanced oscillator 平衡振荡器 can greatly affect the performance of an RF circuit.

一个平衡振荡器 balanced oscillator 的设计可以极大地影响射频电路的性能。

4.A balanced oscillator 平衡振荡器 can be implemented using various components like transistors and capacitors.

可以使用各种组件，如晶体管和电容器，来实现平衡振荡器 balanced oscillator 。

5.The output of a balanced oscillator 平衡振荡器 is typically a sine wave or a square wave.

平衡振荡器 balanced oscillator 的输出通常是正弦波或方波。

作文

In the realm of physics and engineering, the concept of a balanced oscillator plays a crucial role in understanding various dynamic systems. A balanced oscillator refers to a system that maintains its equilibrium while oscillating around a central point. This phenomenon can be observed in numerous applications, ranging from simple pendulums to complex electronic circuits. The essence of a balanced oscillator lies in its ability to convert potential energy into kinetic energy and vice versa, allowing it to sustain motion without external interference.One of the most common examples of a balanced oscillator is a mass-spring system. When a mass attached to a spring is displaced from its rest position and released, it begins to oscillate back and forth. The restoring force exerted by the spring pulls the mass back toward its equilibrium position, while the inertia of the mass causes it to overshoot this position, resulting in oscillatory motion. This continuous exchange of energy between kinetic and potential forms characterizes the behavior of a balanced oscillator.In engineering, understanding balanced oscillators is essential for designing systems that require precise control and stability. For instance, in the field of electronics, oscillators are used in radio transmitters and receivers to generate signals at specific frequencies. A well-designed balanced oscillator ensures that these signals remain stable and consistent, which is vital for effective communication.Moreover, the principles of balanced oscillators extend beyond mechanical and electronic systems. In biology, for example, the rhythmic beating of the heart can be likened to an oscillator. The heart's ability to maintain a steady beat is a result of the balance between electrical impulses and the mechanical properties of the heart muscle. Understanding this biological balanced oscillator can lead to advancements in medical technology and treatments for heart-related conditions.The study of balanced oscillators also has implications in the field of economics. Economic cycles, characterized by periods of expansion and contraction, can be viewed through the lens of oscillatory behavior. Just as a balanced oscillator returns to its equilibrium state after oscillating, economies tend to stabilize after experiencing fluctuations. Recognizing these patterns can aid policymakers in making informed decisions to foster economic stability.In conclusion, the concept of a balanced oscillator is fundamental across various disciplines, illustrating the interconnectedness of different fields of study. From physics to biology and economics, the principles governing balanced oscillators provide valuable insights into the behavior of dynamic systems. By further exploring and understanding these concepts, we can develop more efficient technologies, improve our health, and enhance our understanding of complex systems. As we continue to delve into the intricacies of balanced oscillators, we unlock new possibilities for innovation and discovery in our ever-evolving world.

在物理和工程领域，平衡振荡器的概念在理解各种动态系统中发挥着至关重要的作用。平衡振荡器是指一个在中心点周围振荡时保持其平衡的系统。这种现象可以在许多应用中观察到，从简单的摆到复杂的电子电路。平衡振荡器的本质在于它能够将势能转化为动能，反之亦然，使其能够在没有外部干扰的情况下维持运动。最常见的平衡振荡器例子是质量-弹簧系统。当一个附着在弹簧上的质量从其静止位置被位移并释放时，它开始来回振荡。弹簧施加的恢复力将质量拉回到其平衡位置，而质量的惯性则使其超越这一位置，从而导致振荡运动。这种动能与势能之间的持续交换特征描述了平衡振荡器的行为。在工程学中，理解平衡振荡器对于设计需要精确控制和稳定性的系统至关重要。例如，在电子学领域，振荡器用于无线电发射机和接收机，以生成特定频率的信号。设计良好的平衡振荡器确保这些信号保持稳定和一致，这对有效的通信至关重要。此外，平衡振荡器的原理延伸到机械和电子系统之外。在生物学中，例如，心脏的有节奏跳动可以类比为一个振荡器。心脏维持稳定跳动的能力是电信号和心肌机械特性之间平衡的结果。理解这种生物学上的平衡振荡器可以推动医疗技术的进步以及对心脏相关疾病的治疗。平衡振荡器的研究在经济学领域也具有重要意义。经济周期以扩张和收缩的时期为特征，可以通过振荡行为的视角来看待。就像平衡振荡器在振荡后返回其平衡状态一样，经济在经历波动后往往会稳定下来。识别这些模式可以帮助政策制定者做出明智的决策，以促进经济稳定。总之，平衡振荡器的概念在各个学科中都是基础，展示了不同研究领域之间的相互联系。从物理学到生物学和经济学，支配平衡振荡器的原理为动态系统的行为提供了宝贵的见解。通过进一步探索和理解这些概念，我们可以开发更高效的技术，改善我们的健康，并增强我们对复杂系统的理解。随着我们继续深入研究平衡振荡器的复杂性，我们为在不断发展的世界中创新和发现开辟了新的可能性。