self-contained system

简明释义

独立装置

英英释义

例句

1.Each module in the educational program acts as a self-contained system, allowing students to learn at their own pace.

教育项目中的每个模块都作为一个自给自足的系统运作，使学生能够按自己的节奏学习。

2.The solar power unit functions as a self-contained system, providing energy without external sources.

这个太阳能电源单元作为一个自给自足的系统运行，提供无需外部来源的能源。

3.In software engineering, a microservice can be considered a self-contained system that operates independently.

在软件工程中，微服务可以被视为一个独立运行的自给自足的系统。

4.The RV is designed to be a self-contained system with its own water supply and waste disposal.

这辆房车设计为一个拥有自我水源和废物处理的自给自足的系统。

5.The research lab is a self-contained system equipped with everything needed for experiments.

这个研究实验室是一个配备了所有实验所需设备的自给自足的系统。

作文

In today's rapidly evolving technology landscape, the concept of a self-contained system has gained significant attention. A self-contained system refers to a system that operates independently and is complete in itself, without relying on external resources or components. This idea can be applied across various fields, including software development, engineering, and even ecological systems. Understanding the characteristics and benefits of a self-contained system is crucial for both professionals and students alike.One of the primary advantages of a self-contained system is its ability to function autonomously. In software development, for instance, a self-contained system can run on its own without needing to connect to a larger network or database. This independence not only enhances reliability but also simplifies troubleshooting. Developers can test and deploy applications more efficiently when they are designed as self-contained systems. This reduces the complexity often associated with interdependent systems, where one component's failure can lead to a cascade of issues throughout the entire network.Moreover, self-contained systems promote modularity. By encapsulating all necessary functionalities within a single unit, these systems allow for easier updates and maintenance. For example, in the realm of engineering, a self-contained system could refer to a compact power generator that provides energy for a specific application without needing additional support from an external power grid. This modular approach not only saves space but also enhances efficiency, making it particularly appealing in remote or resource-limited environments.Another critical aspect of self-contained systems is their potential for increased security. When a system does not require constant communication with external entities, it minimizes the risk of exposure to cyber threats. This is particularly relevant in today’s digital age, where data breaches and hacking attempts are prevalent. By designing systems that are self-contained, organizations can better protect sensitive information and maintain control over their operational environments.In addition to practical benefits, self-contained systems also have philosophical implications. They encourage a mindset of sustainability and self-sufficiency. In ecological contexts, for example, a self-contained system might describe an ecosystem that maintains its balance and harmony without outside intervention. Such systems are vital for understanding how natural processes work and how we can design human-made systems that mimic these principles.Despite the numerous advantages, it is essential to recognize that self-contained systems are not without limitations. The initial development of such systems may require more resources and time, as every necessary component must be integrated from the start. Additionally, while they excel in certain scenarios, self-contained systems may not be suitable for all applications. For instance, large-scale operations that benefit from shared resources and collaborative efforts might find traditional interconnected systems more effective.In conclusion, the concept of a self-contained system plays a pivotal role in various domains, from technology to ecology. Its emphasis on independence, modularity, and security makes it an attractive option for many applications. However, the decision to implement a self-contained system should be made thoughtfully, considering the specific needs and context of the situation. As we continue to innovate and adapt to new challenges, the principles behind self-contained systems will undoubtedly remain relevant and influential in shaping our future.

在当今快速发展的技术环境中，“自给自足系统”的概念引起了广泛关注。“自给自足系统”是指一个独立运作、完整自足的系统，无需依赖外部资源或组件。这个理念可以应用于多个领域，包括软件开发、工程甚至生态系统。理解“自给自足系统”的特征和优势对专业人士和学生来说都至关重要。“自给自足系统”的主要优势之一是其自主运作的能力。例如，在软件开发中，“自给自足系统”可以独立运行，而无需连接到更大的网络或数据库。这种独立性不仅提高了可靠性，还简化了故障排除。当应用程序被设计为“自给自足系统”时，开发人员可以更高效地进行测试和部署。这减少了与相互依赖的系统相关的复杂性，因为一个组件的故障可能导致整个网络的一系列问题。此外，“自给自足系统”还促进了模块化。通过将所有必要功能封装在一个单元内，这些系统使得更新和维护变得更加容易。例如，在工程领域，“自给自足系统”可以指一个紧凑型发电机，为特定应用提供能量，而无需额外依赖外部电网。这种模块化方法不仅节省了空间，还提高了效率，使其在偏远或资源有限的环境中特别有吸引力。“自给自足系统”的另一个关键方面是其潜在的安全性提升。当一个系统不需要与外部实体进行持续通信时，它就能最大限度地降低暴露于网络威胁的风险。这在当今数字时代尤为相关，因为数据泄露和黑客攻击屡见不鲜。通过设计“自给自足系统”，组织可以更好地保护敏感信息，并保持对其操作环境的控制。除了实际利益外，“自给自足系统”还具有哲学意义。它们鼓励可持续性和自给自足的思维方式。例如，在生态背景下，“自给自足系统”可以描述一个在没有外界干预的情况下维持其平衡与和谐的生态系统。这类系统对于理解自然过程如何运作以及我们如何设计模仿这些原则的人造系统至关重要。尽管有众多优点，但必须认识到“自给自足系统”并非没有局限性。此类系统的初始开发可能需要更多的资源和时间，因为每个必要组件必须从一开始就整合。此外，虽然它们在某些场景中表现出色，但“自给自足系统”可能并不适合所有应用。例如，大规模运营可能会发现共享资源和协作努力的传统互联系统更为有效。总之，“自给自足系统”的概念在多个领域中发挥着关键作用，从技术到生态。其强调独立性、模块化和安全性的特点使其成为许多应用的理想选择。然而，实施“自给自足系统”的决策应经过深思熟虑，考虑到具体需求和情境。随着我们继续创新和适应新挑战，“自给自足系统”背后的原则无疑将在塑造我们的未来中保持相关性和影响力。