Real Life Applications of Area

Last Updated : 03 May, 2024

Area is a fundamental concept in mathematics, which helps us understand space and surfaces. Area is a necessary element of our everyday lives. Area allows us to solve practical problems, it enables us to study and preserve natural ecosystems in environmental science.

Measuring the area of floors and walls is essential for tasks such as laying tiles or carpets on the floor, painting walls, and fitting cupboards in a room. In this article, we will explore the uses and real-life applications of area, in various fields such as architecture, agriculture, real estate, environmental science, and education.

What is Area

Space occupied by the boundary of a figure is called the area of the figure. It is measured in the unit square.

SI unit to measure the area is m². The area is used in various mathematical concepts and is also used in real-life scenarios such as to find the area of the room, area table, etc., and others. The area of some common figures is shown in the image added below:

Area-Formulas

Real Life Application of Area

Area calculations find application in a diverse array of fields, ranging from architecture and agriculture to environmental science and education. By quantifying the extent of surfaces and spaces, area measurements enable us to make informed decisions, optimize resource utilization, and design systems with efficiency and precision.

Let us learn more about how Area are useful in these particular fields.

1. Architecture and Construction

As in our daily life, There are many construction project where we need to calculate the area. Architects use area measurements to Calculating floor area, wall surface area, and roof area for building design and construction. From calculating the area of floors and walls to determining roof coverage, precise measurements enable architects to create suitable functional spaces.

2. Agriculture

Area play a crucial role in modern agriculture. Farmers rely on these calculations to manage land efficiently and maximize crop yields. By measuring field sizes and planning planting patterns, farmers can optimize resource usage, minimize waste, and enhance agricultural productivity. Area calculations also inform decisions regarding irrigation, fertilization, and pest control strategies.

3. Education

In classrooms around the world, area concepts serve as fundamental elements of mathematical education. Students learn to calculate areas of geometric shapes, fostering spatial reasoning skills and problem-solving abilities. Through hands-on activities and real-world applications, educators instill a deeper understanding of the practical relevance of mathematics in everyday life.

4. Resource Management

Area calculations are used to quantify the size and extent of natural resources such as forests, wetlands, and wildlife habitats. This involves measuring the area of these ecosystems using techniques such as satellite imagery, aerial surveys, and ground-based measurements. Once the areas of natural resources are assessed, ongoing monitoring is essential to track changes over time. Area calculations also play a role in identifying and maintaining habitat connectivity corridors, which are essential for wildlife movement and genetic exchange.

5. Transportation

In transportation engineering, area calculations play a crucial role in the design and planning of roads, highways, and parking lots to ensure efficient traffic flow and safety.

When designing roads and highways, engineers need to calculate the total area of pavement required for the specified lane widths, shoulders, and medians. By accurately determining the surface area of the roadway, engineers can ensure that there is adequate space for vehicles to travel safely and efficiently. Engineers calculate the area of intersection layouts to accommodate turning radii for various vehicle types, pedestrian crossings, and traffic islands. Area calculations are also used in traffic flow analysis to evaluate the capacity and performance of transportation infrastructure.

6. Urban Planning and Design

Urban planning and design are multidisciplinary processes aimed at creating sustainable, functional, and aesthetically pleasing urban environments. Area calculations serve as fundamental tools in these endeavors, guiding the planning and design of cities, streets, parks, and public spaces.

Urban planners utilize area calculations to assess land use patterns and zoning regulations. By measuring the area of different land parcels and zoning districts, planners can determine the suitability of specific areas for residential, commercial, industrial, or recreational purposes. Area calculations play a crucial role in designing streets, roads, and transportation networks within urban areas. Parks and green spaces are essential components of urban environments, providing recreational opportunities and ecological benefits. Area calculations guide the planning and design of parks by determining the size, shape, and layout of green spaces. Sustainable development principles are integrated into urban planning and design processes to minimize environmental impact and enhance quality of life.

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Calculus: In calculus, the area under a curve is often used to calculate integrals and solve problems related to finding the area of irregular shapes or the accumulated effect of changing quantities over time. Integrating a function over a specified interval allows mathematicians to determine the total amount represented by the function.

Physics: In physics, the area under a curve often represents physical quantities such as displacement, velocity, acceleration, force, energy, or power. For example, the area under a velocity-time graph represents the displacement of an object, while the area under a force-distance graph represents the work done on an object.

Engineering: Engineers use the area under curves to analyze and design systems and structures. For example, in structural engineering, the area under a stress-strain curve represents the resilience of a material or its ability to absorb energy before failure. In electrical engineering, the area under a voltage-time curve represents the electrical energy delivered over time.

Economics: In economics, the area under supply and demand curves represents quantities such as consumer surplus, producer surplus, total revenue, or total cost. Economists use these concepts to analyze market behavior, evaluate policy interventions, and assess welfare effects.

Probability and Statistics: In probability and statistics, the area under a probability density function (PDF) or a cumulative distribution function (CDF) represents probabilities or cumulative probabilities associated with specific events or outcomes. Statisticians use these concepts to compute probabilities, analyze data distributions, and make statistical inferences.

Summary – Real Life Applications of Area

The concept of area is a cornerstone in both mathematics and real life, influencing a vast array of fields from architecture and agriculture to transportation and urban planning. It allows us to understand and optimize the space we live in and work with. Whether it’s architects designing buildings, farmers maximizing their crop yields, educators teaching the next generation, environmental scientists preserving natural habitats, or engineers planning roads and cities, the calculation of area is pivotal. By measuring spaces and surfaces, we can make more informed decisions, use resources efficiently, and create sustainable, functional environments. In essence, understanding and applying area calculations help shape the world around us, ensuring we utilize spaces effectively for our needs and the planet’s health.