1. Da Nang-05/2015 Natural Science Department – Duy Tan University SPRING MOTION MODEL with Differential Equations In this section, we will learn: How to represent some mathematical models in the form of differential equations.

2.  We consider the motion of an object with mass m at the end of a vertical spring. MODEL FOR MOTION OF A SPRING

3.  If the spring is stretched (or compressed) x units from its natural length, it exerts a force proportional to x: restoring force = -kx where k is a positive constant (the spring constant). MODEL FOR MOTION OF A SPRING

4.  If we ignore any external resisting forces (due to air resistance or friction) then, by Newton’s Second Law, we have: SPRING MOTION MODEL Equation 3

5.  This is an example of a second-order differential equation.  It involves second derivatives. SECOND-ORDER DIFFERENTIAL EQUATION

6. SPRING MOTION MODEL  Let’s see what we can guess about the form of the solution directly from the equation.

7.  We can rewrite Equation 3 in the form  This says that the second derivative of x is proportional to x but has the opposite sign. SPRING MOTION MODEL

8.  We know two functions with this property, the sine and cosine functions.  It turns out that all solutions of Equation 3 can be written as combinations of certain sine and cosine functions. SPRING MOTION MODEL

9.  This is not surprising.  We expect the spring to oscillate about its equilibrium position.  So, it is natural to think that trigonometric functions are involved. SPRING MOTION MODEL

10.  In general, a differential equation is an equation that contains an unknown function and one or more of its derivatives. GENERAL DIFFERENTIAL EQUATIONS

11. ORDER  The order of a differential equation is the order of the highest derivative that occurs in the equation.

12.  In all three equations, the independent variable is called t and represents time.  However, in general, it doesn’t have to represent time. INDEPENDENT VARIABLE

13. LOGO Thank you for your attention