Paul Bunuan

Paul Bunuan

Answered question

2022-09-28

Answer & Explanation

Eliza Beth13

Eliza Beth13

Skilled2023-05-31Added 130 answers

To solve the given first-order differential equation (DE), we'll use the method of integrating factors. The DE is as follows:
ty+(t+1)y=2tetwithy(1)=a
Rewrite the DE in standard form
To simplify the equation, we divide both sides by t:
y+(1+1t)y=2et
Identify the integrating factor
The integrating factor for this DE is given by the exponential of the integral of the coefficient of y, which is (1+1t). Let's calculate it:
(1+1t)dt=t+1tdt=(1+1t)dt=t+ln|t|+C
So, the integrating factor is et+ln|t|=tet.
Multiply the DE by the integrating factor
Multiply both sides of the DE by tet:
tety+tet(1+1t)y=2tetet
Simplifying, we have:
tety+(t+1)yet=2t
Apply the product rule on the left side
To apply the product rule, let's define u(t)=yet. Now, we can differentiate u(t):
ddt(u(t))=ddt(yet)
Using the product rule, we get:
u(t)=yet+yet
Rewrite the DE using u(t)
Substituting the expressions from Step 4 into the DE, we have:
tet(u(t))+(t+1)u(t)=2t
Solve the resulting linear DE
The DE obtained in Step 5 is linear, so we can solve it using standard methods. First, let's rearrange the equation:
tetu(t)+(t+1)u(t)=2t
Integrate both sides
Integrating both sides of the equation, we obtain:
tetu(t)dt+(t+1)u(t)dt=2tdt
Evaluate the integrals
Let's calculate the integrals one by one:
tetu(t)dt=u(t)du(using substitution)
(t+1)u(t)dt=(t+1)(yet)dt
2tdt=t2
Simplify the equation
Substituting the results back into the equation, we have:
u(t)+(t+1)(yet)dt=t2
Evaluate the remaining integral
Let's calculate the remaining integral:
(t+1)(yet)dt
Expanding the expression and using integration by parts, we get:
(t+1)(yet)dt=(tyet+yet)dt
Using integration by parts, with v=et and du=(t+1)yetdt, we find:
(t+1)(yet)dt=(tyetetdt)+C
(t+1)(yet)dt=tyetet+C
Substitute back into the equation
Substituting the result of the integral into the equation
u(t)+(tyetet+C)=t2
Solve for u(t)
Rearranging the equation, we get:
u(t)=t2tyet+etC
Solve for y(t)
Recall that we defined u(t)=yet. Substituting this back into the equation, we have:
yet=t2tyet+etC
Simplifying, we get:
yet+tyet=t2+etC
yet(1+t)=t2+etC
y=t2+etCet(1+t)
Apply the initial condition
To find the value of the constant C, we can apply the initial condition y(1)=a. Substituting t=1 and y=a, we get:
a=12+e1Ce1(1+1)
2ae=1+eC
C=1+e2ae
Final solution
Substituting the value of C back into the expression for y(t), we have:
y(t)=t2+et(1+e2ae)et(1+t)
Now, let's determine the range of values of a for which limt0+y=.
As t approaches 0+, the term t2 becomes negligible compared to et. Thus, we can ignore the t2 term. Considering the other terms:
limt0+y(t)=limt0+et(1+e2ae)et(1+t)
As t approaches 0+, the denominator et(1+t) remains positive and nonzero. Hence, for limt0+y(t) to be infinity, the numerator et(1+e2ae) must approach infinity.
Since et approaches 1 as t approaches 0, the condition for limt0+y(t)= is:
1(1+e2ae)=
Simplifying, we get:
e+2ae=
This condition implies that e+2ae should be greater than any finite value, which means that a must be greater than e2.
Therefore, the range of values of a for which limt0+y= is a>e2.

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