mechanical calculation

简明释义

力学计算

英英释义

例句

1.The architect emphasized that mechanical calculation is crucial for ensuring safety in building structures.

建筑师强调，机械计算对于确保建筑结构的安全至关重要。

2.The accountant used mechanical calculation to quickly process the monthly financial reports.

会计师使用机械计算快速处理每月的财务报告。

3.During the workshop, participants learned the importance of mechanical calculation in engineering design.

在研讨会上，参与者了解了机械计算在工程设计中的重要性。

4.The engineer relied on mechanical calculation to determine the load capacity of the bridge.

工程师依赖于机械计算来确定桥梁的承载能力。

5.In the exam, students were asked to perform mechanical calculation for various physics problems.

在考试中，学生们被要求对各种物理问题进行机械计算。

作文

In today's fast-paced world, the importance of efficiency and accuracy in various fields cannot be overstated. One of the key components that contribute to this efficiency is the concept of mechanical calculation, which refers to the process of performing mathematical computations using mechanical devices or automated systems. This method has revolutionized how we approach complex problems, allowing for quick and precise results that would be difficult to achieve manually.

Historically, mechanical calculation emerged with the invention of devices such as the abacus, which enabled users to perform arithmetic operations more rapidly than by hand. As technology advanced, more sophisticated machines like calculators and computers were developed, further enhancing our ability to handle numerical data. In contemporary society, mechanical calculation plays a crucial role in various sectors, including finance, engineering, and scientific research.

In finance, for instance, mechanical calculation is essential for analyzing large datasets to make informed investment decisions. Financial analysts rely on algorithms and computational models to predict market trends and assess risks. The speed at which these calculations can be performed allows firms to stay competitive and respond quickly to market changes. Without mechanical calculation, the financial industry would struggle to manage the vast amounts of data generated daily.

Similarly, in engineering, mechanical calculation is vital for designing structures and systems that are safe and efficient. Engineers use software that incorporates mechanical calculation to simulate real-world conditions and analyze the performance of their designs. This not only saves time but also reduces the likelihood of errors that could lead to catastrophic failures. For example, when designing a bridge, engineers must calculate stress loads, materials' strengths, and environmental factors. The precision offered by mechanical calculation ensures that these structures can withstand the forces they will encounter throughout their lifespan.

Moreover, in scientific research, mechanical calculation is indispensable for processing experimental data. Researchers often conduct experiments that generate massive amounts of data, which must be analyzed to draw meaningful conclusions. Advanced statistical methods and computational tools allow scientists to perform mechanical calculation on this data, leading to new discoveries and innovations. The ability to quickly analyze and interpret data has accelerated the pace of scientific advancement, making it possible to address complex global challenges such as climate change and public health crises.

However, it is essential to recognize that while mechanical calculation offers numerous advantages, it also comes with challenges. One significant concern is the potential for over-reliance on automated systems. When humans depend too much on machines for calculations, there is a risk of losing critical thinking skills and the ability to understand the underlying principles of the computations being performed. Therefore, it is crucial to strike a balance between utilizing mechanical calculation and maintaining a strong foundation in mathematical concepts.

In conclusion, mechanical calculation has transformed the way we approach problem-solving across various fields. Its ability to enhance efficiency and accuracy has made it an indispensable tool in finance, engineering, and scientific research. However, as we continue to embrace automation, we must also ensure that we do not lose sight of the fundamental skills that underpin these processes. By doing so, we can harness the full potential of mechanical calculation while preserving the critical thinking abilities that are essential for innovation and progress.

在当今快节奏的世界中，各个领域对效率和准确性的重视不言而喻。其中一个关键组成部分是机械计算的概念，它指的是使用机械设备或自动化系统进行数学计算的过程。这种方法彻底改变了我们处理复杂问题的方式，使我们能够快速而精确地得出结果，而这些结果是手动操作难以实现的。

历史上，机械计算随着算盘等设备的发明而出现，这使得用户能够比手工更快速地进行算术运算。随着技术的进步，更复杂的机器如计算器和计算机被开发出来，进一步增强了我们处理数字数据的能力。在当代社会，机械计算在金融、工程和科学研究等各个领域发挥着至关重要的作用。

例如，在金融领域，机械计算对于分析大量数据以做出明智的投资决策至关重要。金融分析师依赖算法和计算模型来预测市场趋势和评估风险。这些计算的速度使公司能够保持竞争力，并迅速应对市场变化。如果没有机械计算，金融行业将难以管理每天产生的大量数据。

同样，在工程领域，机械计算对于设计安全高效的结构和系统至关重要。工程师使用包含机械计算的软件来模拟现实条件并分析其设计的性能。这不仅节省了时间，还减少了可能导致灾难性故障的错误的可能性。例如，在设计桥梁时，工程师必须计算应力负荷、材料强度和环境因素。机械计算提供的精确性确保了这些结构能够承受它们在整个生命周期中所遇到的力量。

此外，在科学研究中，机械计算对于处理实验数据不可或缺。研究人员通常进行会生成大量数据的实验，这些数据必须进行分析才能得出有意义的结论。先进的统计方法和计算工具使科学家能够对这些数据进行机械计算，从而带来新的发现和创新。快速分析和解释数据的能力加速了科学进步的步伐，使我们能够应对气候变化和公共卫生危机等复杂的全球挑战。

然而，必须认识到，尽管机械计算提供了许多优势，但它也带来了挑战。其中一个重大问题是对自动化系统的过度依赖。当人们过于依赖机器进行计算时，就有失去批判性思维能力和理解所执行计算的基本原理的风险。因此，找到利用机械计算与保持扎实的数学概念基础之间的平衡至关重要。

总之，机械计算改变了我们在各个领域解决问题的方式。它提高效率和准确性的能力使其成为金融、工程和科学研究中不可或缺的工具。然而，随着我们继续拥抱自动化，我们也必须确保不失去支撑这些过程的基本技能。这样，我们就可以充分利用机械计算的潜力，同时保持创新和进步所必需的批判性思维能力。