Warm-up Problems Solve the IVP . Give the largest interval over which the solution is defined.

Slides:

Advertisements

Similar presentations

Sec. 4.5: Integration by Substitution. T HEOREM 4.12 Antidifferentiation of a Composite Function Let g be a function whose range is an interval I, and.

Advertisements

Ch 2.6: Exact Equations & Integrating Factors

Math 3120 Differential Equations with Boundary Value Problems

Ch 2.6: Exact Equations & Integrating Factors Consider a first order ODE of the form Suppose there is a function  such that and such that  (x,y) = c.

4.1 Antiderivatives and Indefinite Integrals Defn. A function F(x) is an antiderivative of f(x) on an interval I if F '(x)=f(x) for all x in I. ex. Find.

Warm Up. 7.4 A – Separable Differential Equations Use separation and initial values to solve differential equations.

AP Calculus Ms. Battaglia

1Chapter 2. 2 Example 3Chapter 2 4 EXAMPLE 5Chapter 2.

A) Find the velocity of the particle at t=8 seconds. a) Find the position of the particle at t=4 seconds. WARMUP.

EUT CHAPTER 2 : First Order Differential Equations.

5.4 Exponential Functions: Differentiation and Integration The inverse of f(x) = ln x is f -1 = e x. Therefore, ln (e x ) = x and e ln x = x Solve for.

Elimination Day 2. When the two equations don’t have an opposite, what do you have to do? 1.

3.5 – Solving Systems of Equations in Three Variables.

6.3 Separation of Variables and the Logistic Equation Ex. 1 Separation of Variables Find the general solution of First, separate the variables. y’s on.

Mathematics. Session Differential Equations - 2 Session Objectives  Method of Solution: Separation of Variables  Differential Equation of first Order.

4.1 The Indefinite Integral. Antiderivative An antiderivative of a function f is a function F such that Ex.An antiderivative of since is.

CHAPTER Continuity Implicit Differentiation.

First-Order Differential Equations

Warm-up It’s as easy as 1-2-3! 1)Start by separating variables. 2)Integrate both sides. 3) Solve for dy/dx. Solve = k(y – 80) This represents Newton’s.

Chapter 21 Exact Differential Equation Chapter 2 Exact Differential Equation.

Integration by Substitution

Dr. Omar Al Jadaan Assistant Professor – Computer Science & Mathematics General Education Department Mathematics.

4.1 ANTIDERIVATIVES & INDEFINITE INTEGRATION. Definition of Antiderivative  A function is an antiderivative of f on an interval I if F’(x) = f(x) for.

Exponential Growth and Decay 6.4. Separation of Variables When we have a first order differential equation which is implicitly defined, we can try to.

Separable Differential Equations

AP Calculus Ms. Battaglia. Equations are separable if all x terms can be collected with dx and all y terms with dy. The solution procedure is called separation.

Clicker Question 1 Consider the DE y ' = 4x. Using Euler’s method with  x = 0.5 and starting at (0, 0), what is the estimate for y when x = 2 ? – A. y.

DIFFERENTIAL EQUATIONS Note: Differential equations are equations containing a derivative. They can be solved by integration to obtain a general solution.

Warm up Problems More With Integrals It can be helpful to guess and adjust Ex.

Particular Solutions to Differential Equations Unit 4 Day 2.

Solving First-Order Differential Equations A first-order Diff. Eq. In x and y is separable if it can be written so that all the y-terms are on one side.

Clicker Question 1 Suppose a population of gerbils starts with 20 individuals and grows at an initial rate of 6% per month. If the maximum capacity is.

Blue part is out of 50 Green part is out of 50  Total of 100 points possible.

Additional Topics in Differential Equations Copyright © Cengage Learning. All rights reserved.

Chapter 21 Exact Differential Equation Chapter 2 Exact Differential Equation.

5 minutes Warm-Up Solve. 2) 1).

3.1 Solving Systems By Graphing Or Substitution. * A system of equations is a collection of equations in the same variable. *A solution to a system is.

Solving Quadratic Equations. Find the quadratic equation if the solutions are 3 and -2. x = 3 x = -2 Make them equal zero. x – 3 = 0x + 2 = 0 (x – 3)(x.

2.4 – Solving Equations with the Variable on Each Side.

Guided By:- PROF. DIPESH M. BHOGAYATA Prepared By:- Enrollment No ( Civil Engineering ) First Order & First Degree Ordinary Differential.

An IVP would look like Second Order Linear DE’s. Thm. Existence of a Unique Solution Let a 0, a 1, a 2, and g(x) be continuous on an interval containing.

Introduction to Integrals Unit 4 Day 1. Do Now  Write a function for which dy / dx = 2 x.  Can you think of more than one?

DIFFERENTIAL EQUATIONS

Differential Equations

3.3 – Solving Systems of Inequalities by Graphing

MATH 374 Lecture 7 Linear Equations.

Problem of the Day (Calculator Allowed)

MTH1170 Differential Equations

Part (a) Keep in mind that dy/dx is the SLOPE! We simply need to substitute x and y into the differential equation and represent each answer as a slope.

Use power series to solve the differential equation. {image}

Clicker Question 1 Suppose a population of gerbils starts with 20 individuals and grows at an initial rate of 6% per month. If the maximum capacity is.

Some Substitutions If , we separate the variables. If , we multiply by

Warmup Find the exact value. 1. √27 2. –√

Implicit Differentiation

Sec 2.4: Exact Differential Equations

Linear Equations A linear first-order DE looks like Standard form is

5.1 Solving Systems of Equations by Graphing

Use power series to solve the differential equation. y ' = 7xy

Section 10.4 Linear Equations

Differentials; Exact Equations

EXERCISE SET 7 – Differential Equations

Part (a) dy dx = 1+y x dy dx = m = 2

Solve the differential equation using the method of undetermined coefficients. y " + 4y = e 3x 1. {image}

Solve the differential equation using the method of undetermined coefficients. y " + 9y = e 2x {image}

Warm–up Problems Find the interval of convergence and radius of convergence for If , write y – 4y as a single power series.

Example 2B: Solving Linear Systems by Elimination

RAYAT SHIKSHAN SANSTHA’S S.M.JOSHI COLLEGE HADAPSAR, PUNE

9.3 Separable Equations.

Sec 1.5: Linear First-Order DE

Presentation transcript:

Warm-up Problems Solve the IVP . Give the largest interval over which the solution is defined.

Exact Equations Recall that we defined the differential of z = f (x,y) as dz = fx dx + fy dy Ex. Consider x2 – 5xy + y3 = c, find the differential of both sides.

M(x,y)dx + N(x,y)dy is an exact differential if it is the differential of some function f (x,y). A DE of the form M(x,y)dx + N(x,y)dy = 0 is called an exact equation. But how can we identify an exact equation? Thm. M(x,y)dx + N(x,y)dy is an exact differential iff

Ex. Solve 2xy dx + (x2 – 1)dy = 0.

Ex. Solve (e2y – y cos xy)dx + (2xe2y – x cos xy + 2y)dy = 0.

Ex. Solve

To make M(x,y)dx + N(x,y)dy exact, we multiply by an integrating factor: If is in terms of only x, use If is in terms of only y, use

Ex. Solve xy dx + (2x2 + 3y2 – 20)dy = 0.