equivalent system

简明释义

等效系

英英释义

例句

1.The equivalent system used in this experiment helped us achieve more accurate results.

本实验中使用的等效系统帮助我们获得了更准确的结果。

2.The engineers proposed an equivalent system that would reduce costs without sacrificing quality.

工程师们提出了一个等效系统，可以在不牺牲质量的情况下降低成本。

3.In our software, we created an equivalent system to ensure compatibility across different platforms.

在我们的软件中，我们创建了一个等效系统以确保在不同平台上的兼容性。

4.By using an equivalent system, we can analyze the data more effectively.

通过使用一个等效系统，我们可以更有效地分析数据。

5.In physics, we often use an equivalent system to simplify complex problems.

在物理学中，我们经常使用一个等效系统来简化复杂问题。

作文

In today's rapidly evolving technological landscape, the concept of an equivalent system plays a crucial role in various fields, including computer science, engineering, and economics. An equivalent system refers to a setup or framework that can perform the same functions or achieve the same results as another system, albeit through different means or processes. This idea is particularly important when considering the efficiency and adaptability of systems in response to changing demands and challenges.For instance, in computer science, we often encounter different programming languages that can achieve similar outcomes. While one language may be more efficient for a specific task, another might offer better readability or ease of use. In this context, we can consider these programming languages as equivalent systems because they can ultimately produce the same result: a functioning application or program.Moreover, the concept of equivalent systems extends beyond programming languages to include entire software architectures. For example, a microservices architecture can serve as an equivalent system to a monolithic architecture. Both architectures can support the same business functionalities, but they do so through different structural designs. Understanding these equivalent systems allows developers and architects to choose the most suitable approach based on their specific requirements, such as scalability, maintainability, and deployment speed.In the realm of engineering, the idea of equivalent systems is equally significant. Engineers often face the challenge of designing systems that meet specific performance criteria. For example, when designing a bridge, engineers might evaluate different materials and construction techniques that can provide the necessary strength and durability. Each alternative may represent an equivalent system in terms of the bridge's ability to withstand loads and environmental conditions, but the choice of materials can affect costs, construction time, and long-term maintenance.Economics also offers a fascinating perspective on equivalent systems. When analyzing market structures, economists often compare different economic models that can yield similar outcomes. For instance, a perfectly competitive market and a monopolistically competitive market might both lead to efficient resource allocation, even though the underlying mechanisms differ significantly. By understanding these equivalent systems, policymakers can make informed decisions about regulations and interventions that promote economic efficiency and fairness.The importance of recognizing equivalent systems lies in the flexibility it provides. In a world where change is the only constant, being able to identify and implement alternative systems can lead to innovative solutions. It encourages critical thinking and creativity, allowing individuals and organizations to adapt to new challenges and seize opportunities.In conclusion, the concept of an equivalent system is vital across various disciplines, serving as a reminder that multiple paths can lead to the same destination. Whether in technology, engineering, or economics, understanding equivalent systems enhances our ability to innovate and adapt in an ever-changing environment. As we continue to explore and develop new systems, the recognition of their equivalence will remain a key factor in driving progress and ensuring success in our endeavors.

在当今快速发展的技术环境中，等效系统的概念在计算机科学、工程和经济学等多个领域发挥着至关重要的作用。等效系统指的是可以通过不同的手段或过程执行相同功能或实现相同结果的设置或框架。当考虑到系统对变化需求和挑战的响应效率和适应性时，这一理念尤为重要。例如，在计算机科学中，我们经常会遇到能够实现类似结果的不同编程语言。虽然一种语言在特定任务上可能更高效，但另一种语言可能提供更好的可读性或易用性。在这个背景下，我们可以将这些编程语言视为等效系统，因为它们最终可以产生相同的结果：一个可运行的应用程序或程序。此外，等效系统的概念不仅限于编程语言，还包括整个软件架构。例如，微服务架构可以作为单体架构的等效系统。这两种架构都可以支持相同的业务功能，但通过不同的结构设计实现。理解这些等效系统使开发人员和架构师能够根据特定要求（例如可扩展性、可维护性和部署速度）选择最合适的方法。在工程领域，等效系统的理念同样重要。工程师经常面临设计满足特定性能标准的系统的挑战。例如，在设计桥梁时，工程师可能会评估不同的材料和施工技术，这些材料和技术能够提供必要的强度和耐久性。每种替代方案可能代表一个等效系统，在桥梁承受载荷和环境条件方面具有相同的能力，但材料的选择可能会影响成本、施工时间和长期维护。经济学也为等效系统提供了一个引人入胜的视角。在分析市场结构时，经济学家通常比较不同的经济模型，这些模型可以产生类似的结果。例如，完全竞争市场和垄断竞争市场可能都能导致资源的有效配置，即使其基本机制有显著不同。通过理解这些等效系统，政策制定者可以就促进经济效率和公平的法规和干预措施做出明智的决定。认识到等效系统的重要性在于它所提供的灵活性。在变化是唯一常态的世界中，能够识别和实施替代系统可以带来创新的解决方案。它鼓励批判性思维和创造力，使个人和组织能够适应新挑战并抓住机会。总之，等效系统的概念在各个学科中都是至关重要的，提醒我们多条路径可以通向同一目的地。无论是在技术、工程还是经济学中，理解等效系统增强了我们在不断变化的环境中进行创新和适应的能力。随着我们继续探索和开发新系统，认识到它们的等效性将始终是推动进步和确保成功的关键因素。