self-actuated controlled

简明释义

自动控制器

英英释义

例句

1.Our irrigation system is equipped with self-actuated controlled sprinklers that activate based on soil moisture levels.

我们的灌溉系统配备了自驱动控制喷头，根据土壤湿度水平自动激活。

2.The manufacturing process uses self-actuated controlled valves to ensure precise fluid flow.

制造过程使用自驱动控制阀门以确保流体流动的精确性。

3.In robotics, self-actuated controlled arms can perform tasks without external input.

在机器人技术中，自驱动控制的机械臂可以在没有外部输入的情况下执行任务。

4.The vehicle's suspension system is designed with self-actuated controlled features for improved ride comfort.

该车辆的悬挂系统设计有自驱动控制功能，以提高乘坐舒适性。

5.The new HVAC system features a self-actuated controlled mechanism that adjusts the temperature automatically.

新型暖通空调系统具有自驱动控制机制，能够自动调节温度。

作文

In the realm of engineering and automation, the concept of self-actuated controlled systems has gained significant attention. These systems are designed to operate autonomously, responding to changes in their environment without the need for external control mechanisms. This autonomy not only enhances efficiency but also reduces the complexity associated with traditional control systems. For instance, consider a self-regulating thermostat that adjusts the temperature of a room based on the current conditions. It senses the temperature and makes adjustments automatically, embodying the principles of self-actuated controlled technology.The benefits of self-actuated controlled systems extend beyond simple applications like climate control. In industrial settings, these systems can monitor production lines and make real-time adjustments to optimize performance. For example, a manufacturing robot equipped with self-actuated controlled capabilities can detect when a part is misaligned and correct its position without human intervention. This capability not only streamlines operations but also minimizes the risk of errors, leading to higher product quality and reduced waste.Moreover, the integration of self-actuated controlled systems into smart home technologies exemplifies the growing trend towards automation. Smart appliances can learn user preferences and adjust their functions accordingly. A refrigerator, for instance, can monitor its contents and suggest recipes based on available ingredients, all while managing energy consumption through self-actuated controlled features.However, the implementation of self-actuated controlled systems is not without challenges. One significant concern is the reliability of these systems in critical applications. For instance, in healthcare, devices such as insulin pumps must operate flawlessly to ensure patient safety. As such, engineers must prioritize rigorous testing and validation processes to ensure that self-actuated controlled systems perform as intended under various conditions.Furthermore, the ethical implications of autonomous systems must be considered. As machines become more capable of making decisions independently, questions arise regarding accountability and transparency. Who is responsible if a self-actuated controlled system malfunctions and causes harm? These concerns necessitate a careful approach to the design and deployment of such technologies.In conclusion, self-actuated controlled systems represent a significant advancement in automation and control technology. Their ability to operate independently offers numerous advantages across various fields, from manufacturing to healthcare. However, as we embrace these innovations, it is essential to address the challenges they present, particularly in terms of reliability and ethics. By doing so, we can harness the full potential of self-actuated controlled systems while ensuring safety and accountability in their application.

在工程和自动化领域，自驱动控制系统的概念受到了广泛关注。这些系统旨在自主运行，根据环境变化做出反应，而无需外部控制机制。这种自主性不仅提高了效率，还减少了与传统控制系统相关的复杂性。例如，考虑一个自我调节的恒温器，它根据当前条件自动调整房间的温度。它感知温度并自动进行调整，体现了自驱动控制技术的原则。自驱动控制系统的好处超出了简单应用，如气候控制。在工业环境中，这些系统可以监控生产线并实时调整以优化性能。例如，配备自驱动控制能力的制造机器人可以检测零件是否错位，并在没有人工干预的情况下纠正其位置。这种能力不仅简化了操作，还最小化了错误风险，从而提高产品质量并减少浪费。此外，将自驱动控制系统集成到智能家居技术中，体现了向自动化发展日益增长的趋势。智能电器可以学习用户偏好并相应调整其功能。例如，冰箱可以监控其内容并根据可用成分建议食谱，同时通过自驱动控制功能管理能耗。然而，实施自驱动控制系统并非没有挑战。其中一个重大问题是这些系统在关键应用中的可靠性。例如，在医疗保健中，像胰岛素泵这样的设备必须完美运行以确保患者安全。因此，工程师必须优先考虑严格的测试和验证过程，以确保自驱动控制系统在各种条件下按预期工作。此外，必须考虑自主系统的伦理影响。随着机器变得越来越能够独立做出决策，责任和透明度的问题随之而来。如果自驱动控制系统发生故障并造成伤害，谁应对此负责？这些问题需要在设计和部署此类技术时采取谨慎的方法。总之，自驱动控制系统代表了自动化和控制技术的重要进步。它们独立运行的能力在从制造到医疗保健等各个领域提供了众多优势。然而，随着我们接受这些创新，必须解决它们带来的挑战，特别是在可靠性和伦理方面。通过这样做，我们可以充分利用自驱动控制系统的潜力，同时确保其应用中的安全性和问责制。