Estimating the Definite Integral Using Left-Endpoint Approximation: A Step-by-Step Guide

Left-Endpoint Approximation

Left-Endpoint Approximation is a numerical method used to estimate the value of a definite integral

Left-Endpoint Approximation is a numerical method used to estimate the value of a definite integral. It is one of the simplest and most basic techniques in numerical integration.

To understand this method, let’s start by considering a function f(x) that is continuous on the interval [a, b]. We want to find the area under the curve of f(x) on this interval.

The left-endpoint approximation divides the interval [a, b] into n subintervals of equal width, where the width of each subinterval is given by h = (b-a) / n. It then approximates the area under the curve on each subinterval by using the value of the function at the left endpoint of the subinterval.

The formula for the left-endpoint approximation is as follows:

Approximation = h * [f(a) + f(a + h) + f(a + 2h) + … + f(a + (n-1)h)]

In this formula, f(a) represents the value of the function f(x) at the left endpoint of the interval, f(a + h) represents the value of the function at the left endpoint of the second subinterval, and so on.

To compute the approximate value of the definite integral using the left-endpoint approximation, we need to evaluate the function at these left endpoints and sum up their values multiplied by the width of each subinterval.

Here’s a step-by-step example to demonstrate the left-endpoint approximation:

1. Consider the function f(x) = x^2 on the interval [1, 3]. We want to estimate the definite integral of f(x) on this interval.

2. Choose the number of subintervals, n. Let’s say we choose n = 4 for this example.

3. Compute the width of each subinterval, h = (b-a) / n = (3-1) / 4 = 0.5

4. Evaluate the function at the left endpoints of each subinterval:
For the first subinterval, x = a = 1, so f(a) = f(1) = 1^2 = 1
For the second subinterval, x = a + h = 1 + 0.5 = 1.5, so f(a + h) = f(1.5) = (1.5)^2 = 2.25
For the third subinterval, x = a + 2h = 1 + 2(0.5) = 2, so f(a + 2h) = f(2) = 2^2 = 4
For the fourth subinterval, x = a + 3h = 1 + 3(0.5) = 2.5, so f(a + 3h) = f(2.5) = (2.5)^2 = 6.25

5. Calculate the left-endpoint approximation by summing the values of the function at each left endpoint multiplied by the width of each subinterval:
Approximation = h * [f(a) + f(a + h) + f(a + 2h) + f(a + 3h)]
= 0.5 * [1 + 2.25 + 4 + 6.25]
= 0.5 * 13.5
= 6.75

Therefore, the left-endpoint approximation for the definite integral of f(x) = x^2 on the interval [1, 3] is approximately equal to 6.75.

More Answers:

Finding the Composition of Functions: f(g(x)) = x^6
Determining the Composition of Functions: Simplifying the Expression g(f(x)) = x^(-6)
Understanding Function Composition: How to Find f(g(x)) in Mathematics

Error 403 The request cannot be completed because you have exceeded your quota. : quotaExceeded

Share:

Recent Posts

Mathematics in Cancer Treatment

How Mathematics is Transforming Cancer Treatment Mathematics plays an increasingly vital role in the fight against cancer mesothelioma. From optimizing drug delivery systems to personalizing

Read More »