compensators
简明释义
英[kəmˈpɛn.sə.təz]美[kəmˈpɛn.sə.tɚz]
n. [电][自]补偿器(compensator 的复数);补偿装置
英英释义
单词用法
主动补偿器 | |
被动补偿器 | |
错误补偿器 | |
控制系统中的补偿器 | |
使用补偿器 | |
补偿器的设计 | |
补偿器的性能 | |
补偿器的功能 |
同义词
| 调整器 | The adjusters are used to fine-tune the system's performance. | 调整器用于微调系统的性能。 | |
| 平衡器 | 平衡器有助于保持机械系统的稳定性。 | ||
| 抵消器 | Offsetters are essential in accounting to balance the books. | 抵消器在会计中对平衡账目至关重要。 | |
| 修复器 | 修复器对于恢复受损部件至关重要。 |
反义词
| 贬低者 | The detractors of the policy argued that it would lead to more problems. | 该政策的贬低者辩称这会导致更多问题。 | |
| 惩罚者 | 惩罚者对违规行为施加了严格的罚款。 |
例句
1.Polarization mode dispersion (PMD) in fiber Bragg gratings (FBG) is investigated with the emphasis on the PMD of chirped FBG dispersion compensators.
对光纤光栅的偏振模色散特性进行了深入的研究,特别是啁啾光纤光栅色散补偿器的偏振模色散。
2.Metallic Compensators feature in easy design, compact construction, large compact construction, large compensation, easily installation, etc.
金属补偿器具有设计简单、结构紧凑、补偿量大、安装使用方便等特点。
3.Buoyancy compensators provide buoyancy control for scuba divers by allowing them to inflate or deflate the devices.
浮力补给装置可以让给潜水者以充气或放气控制。
4.Copper tube is the first choice for compensators, surface cooling equipments and other heat exchangers. Here was one piece of copper tube that Occurred leakage in short time after use.
铜管是凝热器、表冷器等热交换器的首选管材,某表冷器铜管在投入使用后短时间内发生泄漏。
5.Using this method, we can realize the low crosstalk multi-wavelength dispersion compensators based on fiber gratings.
使用该方法可以得到具有低串扰的多波长光纤光栅色散补偿器。
6.Technical features and application of new low voltage var compensators are analysed.
分析了新型低压无功补偿装置的技术特点及应用情况。
7.In robotics, compensators help maintain balance and precision during movement.
在机器人技术中,补偿器帮助在运动过程中保持平衡和精确度。
8.The control system utilizes compensators to improve stability and performance.
控制系统利用补偿器来提高稳定性和性能。
9.In engineering, compensators are used to adjust the system's response to changes in load.
在工程中,补偿器用于调整系统对负载变化的响应。
10.The thermal compensators in the building help manage heat expansion and contraction.
建筑中的热补偿器帮助管理热膨胀和收缩。
11.Electrical engineers often design compensators to mitigate the effects of load variations.
电气工程师通常设计补偿器以减轻负载变化的影响。
作文
In the realm of engineering and control systems, the term compensators refers to devices or algorithms that are used to improve the performance and stability of a system. They play a crucial role in various applications, from robotics to aerospace, ensuring that systems respond appropriately to changes in input or environmental conditions. The primary function of compensators is to adjust the system's response by modifying its transfer function, which can lead to enhanced accuracy and reduced overshoot in the output. For instance, in a feedback control system, a well-designed compensator can help maintain the desired output even when faced with disturbances or variations in the input signal.The importance of compensators cannot be overstated, particularly in industries where precision is paramount. In manufacturing processes, for example, compensators are employed to ensure that machines operate within specified tolerances. This not only improves product quality but also minimizes waste and increases efficiency. Similarly, in the field of telecommunications, compensators are utilized to mitigate the effects of noise and signal degradation, thereby enhancing the clarity and reliability of communication.One common type of compensator is the PID (Proportional-Integral-Derivative) controller, which combines three different control actions to achieve the desired system behavior. The proportional component adjusts the output based on the current error, the integral component accounts for past errors, and the derivative component predicts future errors. By tuning these parameters, engineers can design compensators that effectively stabilize systems and improve their dynamic response.Moreover, the design of compensators often involves complex mathematical modeling and simulation. Engineers must analyze the system's characteristics and determine the appropriate compensatory measures to implement. This process may include frequency response analysis, root locus techniques, or state-space representation. The goal is always to achieve a balance between responsiveness and stability, ensuring that the system performs as intended under various conditions.In addition to traditional engineering applications, compensators have found their way into emerging technologies such as autonomous vehicles and artificial intelligence. In these contexts, compensators are essential for processing sensor data and making real-time decisions. For example, an autonomous vehicle must constantly adjust its trajectory based on inputs from cameras and radar systems. Here, compensators help to smooth out the vehicle's movements, providing a safer and more comfortable ride for passengers.As technology continues to evolve, the role of compensators will likely expand further. With the rise of smart systems and IoT (Internet of Things), the need for effective compensation strategies will become increasingly critical. Engineers will be tasked with developing compensators that can adapt to dynamic environments and learn from past experiences, paving the way for more intelligent and autonomous systems.In conclusion, compensators are vital components in the design and implementation of control systems across various fields. Their ability to enhance system performance, maintain stability, and adapt to changing conditions makes them indispensable in modern engineering. As we continue to push the boundaries of technology, the development and refinement of compensators will undoubtedly play a significant role in shaping the future of automation and control.
在工程和控制系统领域,术语补偿器指的是用于改善系统性能和稳定性的设备或算法。它们在从机器人到航空航天的各种应用中发挥着至关重要的作用,确保系统能够适当地响应输入或环境条件的变化。补偿器的主要功能是通过修改系统的传递函数来调整系统的响应,这可以导致输出的精度提高和超调减少。例如,在反馈控制系统中,设计良好的补偿器可以帮助在面对干扰或输入信号变化时保持所需的输出。补偿器的重要性不容小觑,特别是在精度至关重要的行业中。例如,在制造过程中,补偿器被用来确保机器在规定的公差内运行。这不仅提高了产品质量,还最小化了浪费并提高了效率。同样,在电信领域,补偿器用于减轻噪声和信号衰减的影响,从而增强通信的清晰度和可靠性。一种常见的补偿器类型是PID(比例-积分-微分)控制器,它结合了三种不同的控制动作以实现所需的系统行为。比例组件根据当前误差调整输出,积分组件考虑过去的误差,而微分组件则预测未来的误差。通过调整这些参数,工程师可以设计出有效稳定系统并改善其动态响应的补偿器。此外,补偿器的设计通常涉及复杂的数学建模和仿真。工程师必须分析系统的特性,并确定实施的适当补偿措施。这个过程可能包括频率响应分析、根轨迹技术或状态空间表示。目标始终是实现响应性与稳定性之间的平衡,确保系统在各种条件下按预期执行。除了传统的工程应用,补偿器还出现在诸如自主车辆和人工智能等新兴技术中。在这些背景下,补偿器对于处理传感器数据和实时决策至关重要。例如,自主车辆必须不断根据来自摄像头和雷达系统的输入调整其轨迹。在这里,补偿器有助于平滑车辆的运动,为乘客提供更安全、更舒适的乘坐体验。随着技术的不断发展,补偿器的角色可能会进一步扩展。随着智能系统和物联网(IoT)的兴起,有效的补偿策略的需求将变得越来越关键。工程师将被要求开发能够适应动态环境并从过去经验中学习的补偿器,为更智能和自主的系统铺平道路。总之,补偿器是各种领域控制系统设计和实施中的重要组成部分。它们增强系统性能、维持稳定性和适应变化条件的能力,使其在现代工程中不可或缺。随着我们继续推动技术的边界,补偿器的发展和完善无疑将在塑造自动化和控制的未来中发挥重要作用。
