Mathematics Exam  >  Mathematics Notes  >  Calculus  >  Real Roots, First Order Differential Equations

Real Roots, First Order Differential Equations | Calculus - Mathematics PDF Download

It’s time to start solving constant coefficient, homogeneous, linear, second order differential equations. So, let’s recap how we do this from the last section. We start with the differential equation.
Real Roots, First Order Differential Equations | Calculus - Mathematics
Write down the characteristic equation.
Real Roots, First Order Differential Equations | Calculus - Mathematics
Solve the characteristic equation for the two roots, r1 and r2. This gives the two solutions
Real Roots, First Order Differential Equations | Calculus - Mathematics
Now, if the two roots are real and distinct (i.e. r1≠r2) it will turn out that these two solutions are “nice enough” to form the general solution
Real Roots, First Order Differential Equations | Calculus - Mathematics
As with the last section, we’ll ask that you believe us when we say that these are “nice enough”. You will be able to prove this easily enough once we reach a later section.
With real, distinct roots there really isn’t a whole lot to do other than work a couple of examples so let’s do that.

Example 1: Solve the following IVP.
Real Roots, First Order Differential Equations | Calculus - Mathematics
Solution: The characteristic equation is
Real Roots, First Order Differential Equations | Calculus - Mathematics
Its roots are r1=−8 and r2=−3 and so the general solution and its derivative is.
Real Roots, First Order Differential Equations | Calculus - Mathematics
Now, plug in the initial conditions to get the following system of equations.
Real Roots, First Order Differential Equations | Calculus - Mathematics
Solving this system gives c1=7/5 and c2=−7/5. The actual solution to the differential equation is then
Real Roots, First Order Differential Equations | Calculus - Mathematics

Example 2: Solve the following IVP
Real Roots, First Order Differential Equations | Calculus - Mathematics
Solution: The characteristic equation is
Real Roots, First Order Differential Equations | Calculus - Mathematics
Its roots are r1=−5 and r2=2 and so the general solution and its derivative is.
Real Roots, First Order Differential Equations | Calculus - Mathematics
Now, plug in the initial conditions to get the following system of equations.
Real Roots, First Order Differential Equations | Calculus - Mathematics
Solving this system gives c1=10/7 and c2=18/7. The actual solution to the differential equation is then
Real Roots, First Order Differential Equations | Calculus - Mathematics

Example 3: Solve the following IVP.
Real Roots, First Order Differential Equations | Calculus - Mathematics
Solution: The characteristic equation is
Real Roots, First Order Differential Equations | Calculus - Mathematics
Its roots are r1=4/3 and r2=−2 and so the general solution and its derivative is.
Real Roots, First Order Differential Equations | Calculus - Mathematics
Now, plug in the initial conditions to get the following system of equations.
Real Roots, First Order Differential Equations | Calculus - Mathematics
Solving this system gives
c1=−9 and c2=3. The actual solution to the differential equation is then.
Real Roots, First Order Differential Equations | Calculus - Mathematics

Example 4: Solve the following IVP
Real Roots, First Order Differential Equations | Calculus - Mathematics
Solution: The characteristic equation is
Real Roots, First Order Differential Equations | Calculus - Mathematics
The roots of this equation are r1=0 and r2=5/4. Here is the general solution as well as its derivative.
Real Roots, First Order Differential Equations | Calculus - Mathematics
Up to this point all of the initial conditions have been at t=0 and this one isn’t. Don’t get too locked into initial conditions always being at t=0 and you just automatically use that instead of the actual value for a given problem.
So, plugging in the initial conditions gives the following system of equations to solve.
Real Roots, First Order Differential Equations | Calculus - Mathematics
Solving this gives.
Real Roots, First Order Differential Equations | Calculus - Mathematics
The solution to the differential equation is then.
Real Roots, First Order Differential Equations | Calculus - Mathematics
In a differential equations class most instructors (including me….) tend to use initial conditions at t=0 because it makes the work a little easier for the students as they are trying to learn the subject. However, there is no reason to always expect that this will be the case, so do not start to always expect initial conditions at t=0!
Let’s do one final example to make another point that you need to be made aware of.

Example 5: Find the general solution to the following differential equation.
Real Roots, First Order Differential Equations | Calculus - Mathematics
Solution: The characteristic equation is.
Real Roots, First Order Differential Equations | Calculus - Mathematics
The roots of this equation are.
Real Roots, First Order Differential Equations | Calculus - Mathematics
Now, do NOT get excited about these roots they are just two real numbers.
Real Roots, First Order Differential Equations | Calculus - Mathematics
Admittedly they are not as nice looking as we may be used to, but they are just real numbers. Therefore, the general solution is
Real Roots, First Order Differential Equations | Calculus - Mathematics
If we had initial conditions we could proceed as we did in the previous two examples although the work would be somewhat messy and so we aren’t going to do that for this example.
The point of the last example is make sure that you don’t get to used to “nice”, simple roots. In practice roots of the characteristic equation will generally not be nice, simple integers or fractions so don’t get too used to them!

The document Real Roots, First Order Differential Equations | Calculus - Mathematics is a part of the Mathematics Course Calculus.
All you need of Mathematics at this link: Mathematics
112 videos|65 docs|3 tests

FAQs on Real Roots, First Order Differential Equations - Calculus - Mathematics

1. What are real roots in the context of first-order differential equations?
Ans. Real roots in the context of first-order differential equations refer to the values of the independent variable (usually denoted by x) for which the corresponding dependent variable satisfies the differential equation. These roots are real numbers that make the equation true.
2. How can we determine if a first-order differential equation has real roots?
Ans. To determine if a first-order differential equation has real roots, we can solve the equation by using appropriate techniques such as separation of variables, integrating factors, or substitution. By solving the equation, we can find the values of x for which the equation holds true, indicating the presence of real roots.
3. Can a first-order differential equation have multiple real roots?
Ans. Yes, a first-order differential equation can have multiple real roots. The number of real roots depends on various factors such as the form of the equation, the initial conditions, and the specific problem being solved. It is possible to have no real roots, one real root, or multiple real roots for a given first-order differential equation.
4. Are all real roots of a first-order differential equation meaningful in the context of the problem being solved?
Ans. Not necessarily. While all real roots of a first-order differential equation are mathematically valid solutions to the equation, not all of them may be meaningful in the context of the problem being solved. The physical or practical significance of the roots depends on the specific problem, and some roots may be extraneous or irrelevant to the problem at hand.
5. How can we interpret the real roots of a first-order differential equation in the context of a real-world problem?
Ans. The interpretation of real roots in the context of a real-world problem depends on the specific problem and the variables involved. Real roots can represent points in time, locations, concentrations, or any other relevant quantity depending on the problem domain. The physical interpretation of the roots should be based on the units and context of the problem, allowing us to understand the behavior or characteristics of the system being modeled by the differential equation.
112 videos|65 docs|3 tests
Download as PDF
Explore Courses for Mathematics exam
Signup for Free!
Signup to see your scores go up within 7 days! Learn & Practice with 1000+ FREE Notes, Videos & Tests.
10M+ students study on EduRev
Related Searches

past year papers

,

Previous Year Questions with Solutions

,

Important questions

,

MCQs

,

Real Roots

,

video lectures

,

Real Roots

,

pdf

,

Summary

,

study material

,

ppt

,

First Order Differential Equations | Calculus - Mathematics

,

Free

,

Exam

,

Sample Paper

,

practice quizzes

,

First Order Differential Equations | Calculus - Mathematics

,

Objective type Questions

,

First Order Differential Equations | Calculus - Mathematics

,

Real Roots

,

shortcuts and tricks

,

mock tests for examination

,

Viva Questions

,

Extra Questions

,

Semester Notes

;