actual computation

简明释义

实际计算;

英英释义

例句

1.In this project, the actual computation 实际计算 will be handled by cloud services.

在这个项目中，实际计算将由云服务处理。

2.The algorithm looks promising, but the actual computation 实际计算 time is still too long.

这个算法看起来很有前景，但实际计算时间仍然太长。

3.We should focus on optimizing the actual computation 实际计算 process to improve efficiency.

我们应该专注于优化实际计算过程，以提高效率。

4.The software can perform simulations, but the actual computation 实际计算 is done on a more powerful server.

该软件可以进行模拟，但实际计算是在更强大的服务器上完成的。

5.Before we present the results, we need to verify the actual computation 实际计算 behind the model.

在我们展示结果之前，我们需要验证模型背后的实际计算。

作文

In today's digital age, the concept of computation has become a fundamental part of our daily lives. Computational processes are at the heart of everything from simple calculations on our smartphones to complex algorithms that drive artificial intelligence. However, it is essential to distinguish between theoretical models of computation and the practical application of these models in real-world scenarios. This is where the term actual computation comes into play. 实际计算 refers to the process of executing a computational model using specific data and resources to achieve a tangible result.To understand actual computation, we can consider various fields such as computer science, mathematics, and engineering. In computer science, for instance, algorithms are designed to solve problems efficiently. However, the performance of an algorithm can only be measured through actual computation. This means running the algorithm on a computer with real input data and measuring how long it takes to complete the task. The results of this process help developers optimize their code and improve overall efficiency. Without actual computation, one could only speculate about the algorithm's effectiveness based on theoretical analysis.Similarly, in mathematics, the distinction between theoretical solutions and actual computation is crucial. For example, while mathematicians may derive formulas to solve equations, the true test of these formulas lies in applying them to specific numerical examples. This application leads to actual computation, which provides insights into the accuracy and reliability of the mathematical principles involved. It is through this practical application that mathematics becomes a powerful tool for solving real-world problems.Moreover, in engineering, actual computation plays a vital role in design and testing processes. Engineers often rely on simulations to predict how structures will behave under various conditions. However, these simulations must be validated through actual computation in physical experiments. For instance, when designing a bridge, engineers will create a model and run tests to see how it holds up under stress. The data gathered from these tests constitute actual computation and inform future designs, ensuring safety and reliability.In addition to its applications in various fields, actual computation also raises important discussions about the limitations of technology. As we continue to advance towards more sophisticated computing systems, the gap between theoretical capabilities and actual computation performance can sometimes widen. Factors such as hardware limitations, software bugs, and unforeseen variables can all affect the outcome of actual computation. Therefore, it is crucial for researchers and practitioners to remain vigilant and continually assess the results of their computations against real-world scenarios.In conclusion, understanding actual computation is vital for anyone involved in fields that rely on computational methods. It bridges the gap between theory and practice, allowing us to evaluate the effectiveness of algorithms, mathematical formulas, and engineering designs. By focusing on actual computation, we can ensure that our theoretical knowledge translates into practical solutions that address real-world challenges. As technology continues to evolve, the importance of actual computation will only grow, making it an essential concept to master for future innovators and problem solvers.

在当今数字时代，计算的概念已成为我们日常生活的基础部分。计算过程是从智能手机上的简单计算到驱动人工智能的复杂算法的核心。然而，区分计算的理论模型和这些模型在现实世界场景中的实际应用至关重要。这就是“actual computation”这一术语的意义所在。“实际计算”指的是使用特定数据和资源执行计算模型以获得可触及结果的过程。要理解actual computation，我们可以考虑计算机科学、数学和工程等各个领域。例如，在计算机科学中，算法被设计用来高效地解决问题。然而，算法的性能只能通过actual computation来衡量。这意味着在计算机上运行算法并使用真实输入数据来测量完成任务所需的时间。这个过程的结果帮助开发人员优化他们的代码，提高整体效率。如果没有actual computation，人们只能根据理论分析推测算法的有效性。同样，在数学中，理论解与actual computation之间的区别至关重要。例如，虽然数学家可能推导出公式来解决方程，但这些公式的真正考验在于将它们应用于特定数值实例。这种应用导致了actual computation，它提供了有关所涉及数学原理的准确性和可靠性的见解。正是通过这种实际应用，数学成为解决现实问题的强大工具。此外，在工程学中，actual computation在设计和测试过程中发挥着至关重要的作用。工程师通常依赖模拟来预测结构在各种条件下的表现。然而，这些模拟必须通过物理实验中的actual computation进行验证。例如，在设计桥梁时，工程师会创建一个模型并进行测试，以查看它在压力下的表现。从这些测试中收集的数据构成了actual computation，并为未来的设计提供信息，确保安全和可靠性。除了在各个领域的应用外，actual computation还引发了关于技术局限性的重要讨论。随着我们不断朝着更复杂的计算系统发展，理论能力与actual computation性能之间的差距有时会扩大。硬件限制、软件错误和不可预见的变量等因素都会影响actual computation的结果。因此，研究人员和从业者必须保持警惕，并持续评估他们的计算结果与现实场景的对比。总之，理解actual computation对于任何参与依赖计算方法的领域的人来说都是至关重要的。它弥合了理论与实践之间的鸿沟，使我们能够评估算法、数学公式和工程设计的有效性。通过关注actual computation，我们可以确保我们的理论知识转化为解决现实挑战的实际解决方案。随着技术的不断发展，actual computation的重要性只会增加，使其成为未来创新者和问题解决者必须掌握的基本概念。