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1_1 Exponential Growth and Decay.flv

1_2 Exponential Growth and Decay.flv

1_3 Exponential Growth and Decay.flv

1_4 Exponential Growth and Decay

1_5 Euler Method

1_6 Euler Method

2_1 Sequences

2_2 Sequences

2_3 Sequences

2_4 Sequences

3_1 Introduction to Series

3_1_1 Introduction to Series

3_2 The Geometric Series

3_3 The Harmonic Series

3_4 Example Problems Involving Series

3_5_1 The Integral Test and Comparison Tests

3_5_2 The Integral Test and Comparison Tests

3_5_3 The Integral Test and Comaprison Tests

3_5_4 The Integral Test and Comparison Tests

3_6_2 Alternating Series

3_6_3 Alternating Series

3_7_1 Absolute Value Test

3_7_2 Ratio and Root Tests.flv

4_1_1 Power Series

4_1_2 Power Series

10_1_1 Vector Function Differentiation

10_1_2 Examples of Vector Function Differentiation

10_1_3 Examples of Vector Function Differentiation

11_1_1 Introduction to the Differentiation of Multivariable Functions

11_1_2 Example Problems on Partial Derivative of a Multivariable Function

11_2_1 The Geomtery of a Multivariable Function

11_3_1 The Gradient of a Multivariable Function

11_3_2 Working towards an equation for a tangent plane to a multivariable point

11_3_4 Working towards an equation for a tangent plane to a multivariable function

11_3_5 When is a multivariable function continuous

11_3_6 Continuity and Differentiablility

11_3_7 A Smooth Function

11_3_8 Example problem calculating a tangent hyperplane

11_4_1 The Derivative of the Composition of Functions

11_4_2 The Derivative of the Composition of Functions

11_5_1 Directional Derivative of a Multivariable Function Part 1

11_5_2 Directional Derivative of a Multivariable Function Part 2

11_6_1 Contours and Tangents to Contours Part 1

11_6_2 Contours and Tangents to Contours Part 2

11_6_3 Contours and Tangents to Contrours Part 3

11_7_1 Potential Function of a Vector Field Part 1

11_7_2 Potential Function of a Vector Field Part 2

11_7_3 Potential Function of a Vector Field Part 3

11_8_1 Higher Order Partial Derivatives Part 1

11_9_1 Derivative of Vector Field Functions

11_9_2 Conservative Vector Fields

12_1_1 Introduction to Taylor Polynomials

12_1_2 An Introduction to Taylor Polynomials

12_1_3 Example problem creating a Taylor Polynomial

12_2_1 Taylor Polynomials of Multivariable Functions

12_2_2 Taylor Theorem for Multivariable Polynomials

13_1 An Introduction to Optimization in Multivariable Functions

13_2 Optimization with Constraints

14_1 The Double Integral

14_2 The Type I Region

14_3 Type II Region with Solved Example Problem

14_4 Some Fun with the Volume of a Cylinder

14_5 The double integral calculated with polar coordinates

14_6 Changing between Type I and II Regions

14_7 Translation of Axes

14_8 The Volume of a Cylinder Revisited

14_9 The Volume between Two Functions

14_10 The Triple Integral by way of an Example Problem

14_11 The Translation of Axes in Triple Integrals

14_12 Translation to Cylindrical Coordinates

15_1 An Introduction to Line Integrals

15_2_1 Example Problem Explaining the Line Integral with Respect to Arc Length

15_2_2 Another Example Problem Solving a Line Integral

15_2_3 Another example problem without using a parametrized curve

15_3_1 Line integrals with respect to coordinate variables

15_3_2 Example problem with line integrals with respect to coordinate variables

15_3_3 Continuation of previous problem

15_4_1 Example problem with the line integral of a multivariable functions

15_4_2 Example problem with the line integral of a multivariable functions

15_4_3 Example problem with the line integrals of a multivariable functions

16_1 Introduction to line integrals of vector fields

16_2 Evaluating the force and the directional vector differential

16_3 Example problem solving the line integral of a vector field

16_4 Another example problem solving for the line integral of a vector field

16_5 Another example problem solving for the line integral of a vector field

16_6 Another problem solving for the line integral in a vector field

16_7 The fundamental theorem of line integrals

16_8 The line integral over a closed path

17_1 The surface integral

17_2 Example problem solving for the surface integral

18_1 Introduction to flux

18_2 Calculating the normal vector

18_3 Example problem for flux

19_1 Greens Theorem

19_1_2 Example problem using theorem of Green to solve for a line integral

19_1_3 Another example problem solving for the line integral using the theorem of Green

19_2 The Theorem of Stokes

19_2_1 Example problem using the theorem of Stokes

19_3_1 Example problem using the theorem of Gauss

100

19_3_2 Example problem using theorem of Gauss

101

Understanding the Euler Lagrange Equation

Description:

Embark on a comprehensive 17-hour journey through advanced calculus and multivariable calculus. Begin with first-order separable differential equations, exploring exponential growth and decay, and the Euler method. Progress through sequences and series, delving into geometric and harmonic series, integral and comparison tests, and power series. Advance to vector functions and multivariable calculus, covering topics such as partial derivatives, gradients, directional derivatives, and Taylor polynomials. Explore optimization, double and triple integrals, and line integrals. Conclude with advanced concepts including Green's Theorem, Stokes' Theorem, and Gauss' Theorem. Master the Euler-Lagrange equation to round out your understanding of advanced calculus principles.

Advanced Calculus - Multivariable Calculus

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#Mathematics #Calculus #Multivariable Calculus #Differential Equations #Partial Derivatives #Power Series

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