compensator

简明释义

英[ˈkɒmpenseɪtə(r)]美[ˈkɑːmpənˌseɪtər]

n. [电][自] 补偿器；自耦变压器；赔偿者；补偿物

复 数 c o m p e n s a t o r s

英英释义

单词用法

同义词

反义词

例句

1.I needed to change my position to being a hirer and mentor and compensator.

威韦罗表示：“我需要调整自己的定位，当个雇佣者、指导者以及补偿者。”

2.The repetitive controller consists of the repetitive compensator and the stability compensator.

重复控制器由重复补偿器和稳定化补偿器组成。

3.COMPENSATOR, a dual capacitor for changing the fuel gaging circuit capacitance due to changes in fuel density.

补偿器，在燃油计量电路中，用来改变电路上的电容，以与燃油密度改变所引起的电容改变相抗衡的双电容器。

4.And provide support for users smelting furnace dedusting equipment used in environmental protection, high voltage capacitor compensator.

并为用户配套提供冶炼炉用的环保除尘设备，高压电容补偿器。

5.The operation of the motion compensator 120 will be described in more detail below.

运动补偿器120的操作将在下文中更加详细地描述。

6.Flexible Hose, Compensator, Oil Return Tube, Flexible Pipe, Metal Pipe, Stainless Steel Corrugated Expansion Pipe.

不锈钢波纹膨胀管、挠性软管、补偿器、金属软管，回油管，网套管。

7.The engineer designed a new compensator to improve the stability of the system.

工程师设计了一个新的补偿器以提高系统的稳定性。

8.In audio equipment, a compensator is used to adjust the frequency response.

在音频设备中，补偿器用于调整频率响应。

9.The flight control system includes a compensator to handle turbulence.

飞行控制系统包括一个补偿器来处理颠簸。

10.A compensator can help correct phase shifts in signal processing.

在信号处理中，补偿器可以帮助修正相位偏移。

11.The robotics team implemented a compensator to enhance the robot's movement accuracy.

机器人团队实施了一个补偿器以增强机器人的运动精度。

作文

In the realm of engineering and technology, the term compensator refers to a device or mechanism that is designed to counterbalance or offset certain parameters in a system. The concept of a compensator is crucial in various fields, including control systems, robotics, and even in everyday appliances. Understanding how a compensator works can provide insights into the efficiency and effectiveness of numerous technological applications. One of the primary functions of a compensator is to enhance the stability of a system. For instance, in control systems, a compensator can be used to adjust the response of a system to ensure that it behaves as desired under varying conditions. This is particularly important in systems where external disturbances may affect performance. By incorporating a compensator, engineers can create a more robust design that maintains optimal performance despite these disturbances. Another significant application of a compensator is in the field of signal processing. In this context, a compensator can help to mitigate the effects of noise or distortion in signals. For example, in audio engineering, a compensator may be employed to balance frequencies, ensuring that the output sound is clear and pleasant to the listener. This illustrates how a compensator not only enhances functionality but also improves user experience. Moreover, compensators are also widely utilized in mechanical systems. For instance, in automotive engineering, a compensator can be found in the suspension system of a vehicle. It helps to absorb shocks and maintain a smooth ride by compensating for irregularities in the road surface. This application highlights how compensators play a vital role in safety and comfort in transportation. The significance of compensators extends beyond technical applications; they are also essential in economic contexts. For example, a financial compensator could refer to mechanisms that adjust payments or benefits based on inflation rates or other economic indicators. This ensures that individuals or organizations do not suffer losses due to changing economic conditions, showcasing the broader applicability of the term. In conclusion, the term compensator encompasses a wide range of devices and mechanisms designed to offset or balance various factors within a system. Whether in engineering, signal processing, mechanical systems, or economic contexts, compensators play an essential role in enhancing stability, performance, and user experience. As technology continues to evolve, understanding the function and importance of compensators will remain critical for engineers, designers, and economists alike. Their ability to adapt and improve systems makes them invaluable in our increasingly complex world.

在工程和技术领域，术语补偿器指的是一种旨在抵消或抵消系统中某些参数的设备或机制。补偿器的概念在控制系统、机器人技术甚至日常电器等多个领域至关重要。理解补偿器的工作原理可以为我们提供对众多技术应用的效率和有效性的深入洞察。 补偿器的主要功能之一是增强系统的稳定性。例如，在控制系统中，可以使用补偿器来调整系统的响应，以确保在不同条件下其行为符合预期。这在外部干扰可能影响性能的系统中特别重要。通过引入补偿器，工程师可以创建更强大的设计，以保持最佳性能，尽管存在这些干扰。 补偿器的另一个重要应用是在信号处理领域。在这种情况下，补偿器可以帮助减轻信号中的噪声或失真的影响。例如，在音频工程中，可能会使用补偿器来平衡频率，确保输出声音清晰且令人愉悦。这说明了补偿器不仅提高了功能性，还改善了用户体验。 此外，补偿器也广泛应用于机械系统。例如，在汽车工程中，车辆的悬挂系统中可以找到补偿器。它有助于吸收冲击并保持平稳的行驶，通过补偿路面不规则性来实现。这一应用突显了补偿器在交通安全和舒适性方面的重要作用。 补偿器的重要性超越了技术应用；在经济背景下，它们同样至关重要。例如，金融补偿器可以指根据通货膨胀率或其他经济指标调整付款或福利的机制。这确保个人或组织不会因经济条件变化而遭受损失，展示了这一术语更广泛的适用性。 总之，术语补偿器涵盖了一系列旨在抵消或平衡系统中各种因素的设备和机制。无论是在工程、信号处理、机械系统还是经济背景下，补偿器在增强稳定性、性能和用户体验方面都发挥着至关重要的作用。随着技术的不断发展，理解补偿器的功能和重要性将继续对工程师、设计师和经济学家至关重要。它们适应和改善系统的能力使其在我们日益复杂的世界中变得不可或缺。