2. Suppose that y₁ is a solution for of the homogeneous SOLDE " + p(t)y' + q(t)y = 0. (a) Explain how to find a non constant function tv(t) such that y2(t) = v(t)y₁(t) is also a solution. (b) Explain why y₁ and y₂ are linearly independent. Suppose that y, is a solution for of the homogeneous SOLDE "I y" +p(t)y +q(t)y = 0. (a) Explain how to find a non constant function t| → v(t) -> such that y2 (t) = v(t)y, (t) is also a solution. (b) Explain why y, and y2 linearly independent. The partial are solution is given below, please give all steps clearly with all math: For (a) you have to derive the method of reduction of order. Indeed, if we want y2 = v(t)y 1(t) to be a solution we get a homogeneous FOLDE with a solution given by v(t) = (-Sp)/(y1(t))^2 dt. For (b), one way is to explain why the v obtained in (a) is not constant and hence y2 is not a scalar multiple of y1. Another possible solution for (b) is to compute the Wronskian of y1 and y2 vy1 and explain why is never 0 =

Advanced Engineering Mathematics
10th Edition
ISBN:9780470458365
Author:Erwin Kreyszig
Publisher:Erwin Kreyszig
Chapter2: Second-order Linear Odes
Section: Chapter Questions
Problem 1RQ
icon
Related questions
Question
2. Suppose that y₁ is a solution for of the homogeneous SOLDE " + p(t)y' + q(t)y = 0.
(a) Explain how to find a non constant function tv(t) such that y2(t) = v(t)y₁(t) is also
a solution.
(b) Explain why y₁ and y₂ are linearly independent.
Transcribed Image Text:2. Suppose that y₁ is a solution for of the homogeneous SOLDE " + p(t)y' + q(t)y = 0. (a) Explain how to find a non constant function tv(t) such that y2(t) = v(t)y₁(t) is also a solution. (b) Explain why y₁ and y₂ are linearly independent.
Suppose that y, is a solution for of the
homogeneous SOLDE
"I
y" +p(t)y +q(t)y = 0. (a) Explain how to
find a non constant function t| → v(t)
->
such that y2 (t) = v(t)y, (t) is also a
solution. (b) Explain why y, and y2
linearly independent. The partial
are
solution is given below, please give all
steps clearly with all math: For (a) you
have to derive the method of reduction
of order. Indeed, if we want y2 = v(t)y
1(t) to be a solution we get a
homogeneous FOLDE with a solution
given by v(t) = (-Sp)/(y1(t))^2 dt.
For (b), one way is to explain why the v
obtained in (a) is not constant and
hence y2 is not a scalar multiple of y1.
Another possible solution for (b) is to
compute the Wronskian of y1 and y2
vy1 and explain why is never 0
=
Transcribed Image Text:Suppose that y, is a solution for of the homogeneous SOLDE "I y" +p(t)y +q(t)y = 0. (a) Explain how to find a non constant function t| → v(t) -> such that y2 (t) = v(t)y, (t) is also a solution. (b) Explain why y, and y2 linearly independent. The partial are solution is given below, please give all steps clearly with all math: For (a) you have to derive the method of reduction of order. Indeed, if we want y2 = v(t)y 1(t) to be a solution we get a homogeneous FOLDE with a solution given by v(t) = (-Sp)/(y1(t))^2 dt. For (b), one way is to explain why the v obtained in (a) is not constant and hence y2 is not a scalar multiple of y1. Another possible solution for (b) is to compute the Wronskian of y1 and y2 vy1 and explain why is never 0 =
AI-Generated Solution
AI-generated content may present inaccurate or offensive content that does not represent bartleby’s views.
steps

Unlock instant AI solutions

Tap the button
to generate a solution

Recommended textbooks for you
Advanced Engineering Mathematics
Advanced Engineering Mathematics
Advanced Math
ISBN:
9780470458365
Author:
Erwin Kreyszig
Publisher:
Wiley, John & Sons, Incorporated
Numerical Methods for Engineers
Numerical Methods for Engineers
Advanced Math
ISBN:
9780073397924
Author:
Steven C. Chapra Dr., Raymond P. Canale
Publisher:
McGraw-Hill Education
Introductory Mathematics for Engineering Applicat…
Introductory Mathematics for Engineering Applicat…
Advanced Math
ISBN:
9781118141809
Author:
Nathan Klingbeil
Publisher:
WILEY
Mathematics For Machine Technology
Mathematics For Machine Technology
Advanced Math
ISBN:
9781337798310
Author:
Peterson, John.
Publisher:
Cengage Learning,
Basic Technical Mathematics
Basic Technical Mathematics
Advanced Math
ISBN:
9780134437705
Author:
Washington
Publisher:
PEARSON
Topology
Topology
Advanced Math
ISBN:
9780134689517
Author:
Munkres, James R.
Publisher:
Pearson,