Studi Kasus: Penerapan Limit Tak Hingga Fungsi Trigonometri dalam Kehidupan Sehari-hari

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The realm of mathematics, particularly calculus, often seems abstract and detached from our daily lives. However, the concepts explored within this discipline, such as limits and functions, have profound implications for understanding and navigating the world around us. One such concept, the limit of trigonometric functions as they approach infinity, finds practical applications in various fields, from engineering to physics. This article delves into a case study that showcases the real-world relevance of this mathematical principle. <br/ > <br/ >#### The Case of the Oscillating Pendulum <br/ > <br/ >Imagine a simple pendulum swinging back and forth. Its motion can be described using trigonometric functions, specifically sine and cosine. As the pendulum swings, its displacement from its equilibrium position can be represented by a sinusoidal wave. Now, let's consider what happens as the pendulum swings for an extended period. The amplitude of the oscillations, or the maximum displacement from the equilibrium position, gradually decreases due to factors like friction and air resistance. This gradual decrease in amplitude can be modeled using the concept of limits. <br/ > <br/ >#### Applying the Limit Concept <br/ > <br/ >As the pendulum swings for an increasingly long time, the amplitude of its oscillations approaches zero. Mathematically, we can express this as the limit of the sine or cosine function as the angle (representing time) approaches infinity. In this case, the limit of the trigonometric function representing the pendulum's displacement approaches zero. This means that the pendulum eventually comes to rest, its oscillations diminishing to an insignificant level. <br/ > <br/ >#### Real-World Implications <br/ > <br/ >This case study demonstrates how the limit of trigonometric functions as they approach infinity can be used to model real-world phenomena. The concept of limits allows us to understand the long-term behavior of oscillating systems, such as pendulums, springs, and even electrical circuits. By applying this mathematical principle, engineers and scientists can predict the eventual state of these systems and design them to function optimally. <br/ > <br/ >#### Conclusion <br/ > <br/ >The case study of the oscillating pendulum highlights the practical relevance of the limit of trigonometric functions as they approach infinity. This mathematical concept provides a powerful tool for understanding and modeling the behavior of oscillating systems in various fields. By applying this principle, we gain insights into the long-term dynamics of these systems, enabling us to design and optimize them for specific applications. The seemingly abstract concept of limits in calculus finds its practical application in the real world, demonstrating the interconnectedness of mathematics and our everyday experiences. <br/ >