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Antiderivatives: Find a Function Given the Second Derivative (Linear)

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This video explains how to find a function given the 2nd derivative by determining antiderivatives.

Antiderivatives: Find a Function Given the Second Derivative (Linear)

Antiderivatives: Find a Function Given the Second Derivative (Linear)

Find an Antiderivative with an Initial Condition

Find an Antiderivative with an Initial Condition

Antiderivatives: Find a Function Given the Second Derivative (Sine)

Antiderivatives: Find a Function Given the Second Derivative (Sine)

The Antiderivative

The Antiderivative

Indefinite Integration of Vector Valued Functions with Initial Conditions

Indefinite Integration of Vector Valued Functions with Initial Conditions

Determine a Trig Function Given a Second Derivative and Initial Conditions

Determine a Trig Function Given a Second Derivative and Initial Conditions

Ex: Basic Indefinite Integration (Polynomial, Exponential, Quotient)

Ex: Basic Indefinite Integration (Polynomial, Exponential, Quotient)

Indefinite Integration of Vector Valued Functions

Indefinite Integration of Vector Valued Functions

The Antiderivative of a Function involving Secant Squared

The Antiderivative of a Function involving Secant Squared

(1.1) Solutions to Differential Equations as Integrals: Form y'(x)=f(x)

(1.1) Solutions to Differential Equations as Integrals: Form y'(x)=f(x)

Ex 1: Antiderivative Concept - Given Information about f(x), Describe F(x)

Ex 1: Antiderivative Concept - Given Information about f(x), Describe F(x)

Ex 2: Antiderivative Concept - Given Information about f(x), Describe F(x)

Ex 2: Antiderivative Concept - Given Information about f(x), Describe F(x)

Given a Derivative Function, Integrate to Find the Original Function

Given a Derivative Function, Integrate to Find the Original Function

Antiderivative App: Find the Velocity and Height Function from the Acceleration Function

Antiderivative App: Find the Velocity and Height Function from the Acceleration Function

Evaluate a Definite Integral Using the Power Rule: Simplify with Exponent Rules First

Evaluate a Definite Integral Using the Power Rule: Simplify with Exponent Rules First

Definite Integral with Discontinuity and U-substitution a/(x-b)^2

Definite Integral with Discontinuity and U-substitution a/(x-b)^2

Solve First Order Initial Value Problems on the TI-89

Solve First Order Initial Value Problems on the TI-89

Ex: Definite Integration Involving Inverse Tangent - 1/(a^2+u^2)

Ex: Definite Integration Involving Inverse Tangent - 1/(a^2+u^2)

Ex: Definite Integration Application - Velocity and Distance

Ex: Definite Integration Application - Velocity and Distance

Ex: Find a Derivative of a Arctangent Function with the Chain Rule

Ex: Find a Derivative of a Arctangent Function with the Chain Rule

Ex 3: Integration Using Trigonometric Substitution

Ex 3: Integration Using Trigonometric Substitution

Definite Integration of Vector Valued Functions

Definite Integration of Vector Valued Functions

(6.2.1) Laplace Transforms of Derivatives / Using Laplace Transforms to Solve Differential Equations

(6.2.1) Laplace Transforms of Derivatives / Using Laplace Transforms to Solve Differential Equations

El antiderivado

El antiderivado

Derivative of a Product Involving Natural Log: y=6x^2*ln(3x)-4x^3

Derivative of a Product Involving Natural Log: y=6x^2*ln(3x)-4x^3

Ex: Find a Derivative of a Product Involving Arcsine

Ex: Find a Derivative of a Product Involving Arcsine

Given the 2nd Derivative of a Vector Function, Find the Components of r'(t) and r(t)

Given the 2nd Derivative of a Vector Function, Find the Components of r'(t) and r(t)

Use Picard's Iteration to Approximate a Solution to a IVP (2 iterations only)

Use Picard's Iteration to Approximate a Solution to a IVP (2 iterations only)

Ex: Find the Particular Solution to a Basic Differential Equation

Ex: Find the Particular Solution to a Basic Differential Equation

(6.1.2) The Existence and Uniqueness of a Laplace Transform

(6.1.2) The Existence and Uniqueness of a Laplace Transform

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