Preface
IV.A. Differential Equations.
Basic Concepts and Definitions.
IV. B.
Solving Differential Equations\
IV.
B.1. Beginning Theory.
IV.
B. 2. The Calculus of Indefinite Integrals: Basic Facts.
IV. C. Motion and Differential
Equations.
IV. D. Geometry and Differential
Equations: Tangent Fields and Integral Curves.
IV. E. Approximating The
Solution to A Differential Equation with Initial Condition.
Euler's Method.
IV. F. Euler
Meets The Position, Cost, and Area Problems:
An Introduction to the
Fundamental Theorem of Calculus
IV. G. Differential Equations
and Area: Variation on A Theme.
IV.H. The Fundamental Theorem
of Calculus: A Differential Equations Approach
IV.H. Appendix:
Proof of The Fundamental Theorem of Calculus for Positive Continuous Functions.
IV. B. 2. The Calculus of Indefinite Integrals: Basic Facts.What if K'(t)=0? Theorem 4.1: Proof Theorem 4.1: Interpretations What if f'(x)=g'(x)? Theorem 4.2 : Proof Theorem 4.2: Interpretations
The Constant of Integration Indefinite Integral Calculus Core Functions Linearity Problems
Constant Velocity Constant Acceleration Problems
What is a Tangent (Direction) Field? What is an Integral Curve? Examples where y' = dy/dx = P(x) Example where y' = dy/dx = P(x, y) Problems
Review of the Differential A Motivating Example:
estimating the solution to an initial value problem Interpretations Euler's Method An Example where y' = P(x,y) Problems
Motion and Euler Revisited Costs and Euler Revisited Area Area Meets Velocity Area Meets Marginal Cost Theorem 4.3
(The Fundamental Theorem, Evaluation Form to Find Area)Problems
Motion and Area An Area Function Solves A Differential Equation Justification Problems