Table of contents

0. Functions7h 52m
1. Limits and Continuity2h 2m
2. Intro to Derivatives1h 33m
3. Techniques of Differentiation3h 18m
4. Applications of Derivatives2h 38m
5. Graphical Applications of Derivatives6h 2m
6. Derivatives of Inverse, Exponential, & Logarithmic Functions2h 37m
7. Antiderivatives & Indefinite Integrals1h 26m
8. Definite Integrals4h 44m
9. Graphical Applications of Integrals2h 27m
- Area Between Curves
  1h 18m
- Introduction to Volume & Disk Method
  1h 8m
10. Physics Applications of Integrals 3h 16m
- Kinematics
  1h 13m
- Work
  2h 3m
11. Integrals of Inverse, Exponential, & Logarithmic Functions2h 34m
12. Techniques of Integration7h 39m
13. Intro to Differential Equations2h 55m
14. Sequences & Series5h 36m
15. Power Series2h 19m
- Introduction to Power Series
  1h 9m
- Taylor Series & Taylor Polynomials
  1h 10m
16. Parametric Equations & Polar Coordinates7h 58m

8. Definite Integrals

Fundamental Theorem of Calculus

Calculus

8. Definite Integrals

Fundamental Theorem of Calculus

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1:47 minutes

Problem 5.3.73

Textbook Question

Derivatives of integrals Simplify the following expressions.

d/d𝓍 ∫₃ˣ (t² + t + 1) dt

Verified step by step guidance

Recognize that the problem involves the Fundamental Theorem of Calculus, which states that if F(x) = ∫ₐˣ f(t) dt, then dF/dx = f(x).

Identify the integral bounds: the lower bound is a constant (3), and the upper bound is the variable (x). This means the derivative will be evaluated at the upper bound.

Apply the Fundamental Theorem of Calculus: d/d𝓍 ∫₃ˣ (t² + t + 1) dt = (t² + t + 1) evaluated at t = x.

Substitute t = x into the integrand: (x² + x + 1).

Conclude that the derivative simplifies to x² + x + 1, as the lower bound being constant does not contribute to the derivative.

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Key Concepts

Here are the essential concepts you must grasp in order to answer the question correctly.

Fundamental Theorem of Calculus

The Fundamental Theorem of Calculus links differentiation and integration, stating that if F is an antiderivative of f on an interval, then the integral of f from a to b can be computed using F(b) - F(a). This theorem is crucial for simplifying expressions involving derivatives of integrals, as it allows us to evaluate the derivative of an integral directly.

Chain Rule

The Chain Rule is a fundamental principle in calculus used to differentiate composite functions. When differentiating an integral with variable limits, the Chain Rule helps in managing the relationship between the outer function (the derivative) and the inner function (the integral), ensuring that we account for changes in the variable of integration.

Definite Integral

A definite integral represents the accumulation of a function's values over a specific interval, providing a numerical result. In the context of the given expression, understanding how to evaluate the definite integral from 3 to x is essential for applying the Fundamental Theorem of Calculus and simplifying the expression correctly.

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Derivatives of integrals Simplify the following expressions.d/d𝓍 ∫₃ˣ (t² + t + 1) dt

Key Concepts

Fundamental Theorem of Calculus

Chain Rule

Definite Integral

Watch next

Derivatives of integrals Simplify the following expressions.

d/d𝓍 ∫₃ˣ (t² + t + 1) dt