differential regulator

简明释义

差动调节器

英英释义

例句

1.We used a differential regulator 差分调节器 to improve the performance of our power supply system.

我们使用了differential regulator 差分调节器来提高我们的电源系统的性能。

2.The engineer explained how the differential regulator 差分调节器 maintains a constant output voltage despite variations in input voltage.

工程师解释了如何通过differential regulator 差分调节器保持输出电压的恒定，尽管输入电压有所变化。

3.The differential regulator 差分调节器 can effectively reduce noise in sensitive electronic devices.

在敏感电子设备中，differential regulator 差分调节器可以有效减少噪声。

4.To achieve better efficiency, we integrated a differential regulator 差分调节器 into our design.

为了实现更好的效率，我们在设计中集成了differential regulator 差分调节器。

5.In the circuit design, the differential regulator 差分调节器 was essential for ensuring stability.

在电路设计中，differential regulator 差分调节器对于确保稳定性至关重要。

作文

In the field of engineering and control systems, the term differential regulator refers to a specific type of control mechanism that adjusts the output of a system based on the difference between a desired setpoint and the actual measured value. This concept is crucial for maintaining stability and performance in various applications, from industrial automation to robotics. Understanding how a differential regulator works can provide insights into its importance in modern technology.A differential regulator operates by continuously monitoring the output of a system and comparing it with a predetermined target. When discrepancies arise, the regulator makes adjustments to minimize these differences. For instance, in a temperature control system, if the current temperature deviates from the desired temperature, the differential regulator will activate heating or cooling mechanisms to bring the temperature back to the target level. This feedback loop is essential for ensuring that systems operate efficiently and effectively.The design of a differential regulator often involves complex mathematical models and algorithms that account for various factors influencing system behavior. Engineers use principles from control theory to create robust regulators that can handle unexpected changes in conditions, such as fluctuations in load or environmental factors. The ability to predict and respond to these changes is what makes a differential regulator an invaluable tool in engineering.Moreover, differential regulators can be found in numerous applications beyond simple temperature control. They are integral components in automotive systems, where they help manage engine performance by regulating fuel injection and ignition timing based on real-time data. In aerospace, differential regulators play a vital role in flight control systems, ensuring that aircraft maintain their intended flight paths despite external disturbances like turbulence.The significance of differential regulators extends to the realm of renewable energy as well. For example, in solar power systems, these regulators help optimize energy output by adjusting the operation of inverters based on the varying sunlight conditions throughout the day. By effectively managing the flow of electricity, differential regulators contribute to the overall efficiency and reliability of renewable energy sources.In summary, the concept of a differential regulator is fundamental to the functioning of many technological systems. Its ability to continuously monitor and adjust output based on real-time feedback ensures that systems remain stable and perform optimally. As technology continues to advance, the role of differential regulators will likely become even more prominent, driving innovations across various fields. Understanding this mechanism not only enhances our knowledge of engineering principles but also highlights the importance of feedback control in achieving desired outcomes in complex systems.

在工程和控制系统领域，术语differential regulator指的是一种特定类型的控制机制，该机制根据期望设定点与实际测量值之间的差异来调整系统的输出。这一概念对于维护各种应用中的稳定性和性能至关重要，从工业自动化到机器人技术。理解differential regulator的工作原理可以为我们提供对其在现代技术中重要性的深入见解。differential regulator通过持续监控系统的输出并将其与预定目标进行比较来运作。当出现差异时，调节器会进行调整以最小化这些差异。例如，在温度控制系统中，如果当前温度偏离期望温度，differential regulator将激活加热或冷却机制，以将温度恢复到目标水平。这种反馈循环对于确保系统高效、有效地运行至关重要。differential regulator的设计通常涉及复杂的数学模型和算法，这些模型和算法考虑了影响系统行为的各种因素。工程师使用控制理论的原理来创建稳健的调节器，以处理负载或环境因素等条件的意外变化。预测和响应这些变化的能力使得differential regulator成为工程中不可或缺的工具。此外，differential regulators不仅在简单的温度控制中找到应用。它们是汽车系统的重要组成部分，帮助通过根据实时数据调节燃油喷射和点火时机来管理发动机性能。在航空航天领域，differential regulators在飞行控制系统中发挥着至关重要的作用，确保飞机在外部干扰（如气流颠簸）下保持预定飞行路径。differential regulators的重要性还延伸到可再生能源领域。例如，在太阳能发电系统中，这些调节器通过根据日照条件的变化调整逆变器的操作来优化能量输出。通过有效管理电力流动，differential regulators有助于提高可再生能源的整体效率和可靠性。总之，differential regulator的概念是许多技术系统功能的基础。它能够根据实时反馈持续监控和调整输出，确保系统保持稳定并最佳运行。随着技术的不断进步，differential regulators的作用可能会变得更加突出，推动各个领域的创新。理解这一机制不仅增强了我们对工程原理的认识，也突显了反馈控制在实现复杂系统理想结果中的重要性。