Respuesta :
Answer:
[tex] y'' + \frac{7}{t} y = 1[/tex]
For this case we can use the theorem of Existence and uniqueness that says:
Let p(t) , q(t) and g(t) be continuous on [a,b] then the differential equation given by:
[tex] y''+ p(t) y' +q(t) y = g(t) , y(t_o) =y_o, y'(t_o) = y'_o[/tex]
has unique solution defined for all t in [a,b]
If we apply this to our equation we have that p(t) =0 and [tex] q(t) = \frac{7}{t}[/tex] and [tex] g(t) =1[/tex]
We see that [tex] q(t)[/tex] is not defined at t =0, so the largest interval containing 1 on which p,q and g are defined and continuous is given by [tex] (0, \infty)[/tex]
And by the theorem explained before we ensure the existence and uniqueness on this interval of a solution (unique) who satisfy the conditions required.
Step-by-step explanation:
For this case we have the following differential equation given:
[tex] t y'' + 7y = t[/tex]
With the conditions y(1)= 1 and y'(1) = 7
The frist step on this case is divide both sides of the differential equation by t and we got:
[tex] y'' + \frac{7}{t} y = 1[/tex]
For this case we can use the theorem of Existence and uniqueness that says:
Let p(t) , q(t) and g(t) be continuous on [a,b] then the differential equation given by:
[tex] y''+ p(t) y' +q(t) y = g(t) , y(t_o) =y_o, y'(t_o) = y'_o[/tex]
has unique solution defined for all t in [a,b]
If we apply this to our equation we have that p(t) =0 and [tex] q(t) = \frac{7}{t}[/tex] and [tex] g(t) =1[/tex]
We see that [tex] q(t)[/tex] is not defined at t =0, so the largest interval containing 1 on which p,q and g are defined and continuous is given by [tex] (0, \infty)[/tex]
And by the theorem explained before we ensure the existence and uniqueness on this interval of a solution (unique) who satisfy the conditions required.
Answer:
The longest interval in which the given initial value problem is certain to have a unique twice-differentiable solution is (0,∞)
Step-by-step explanation:
Given the differential equation:
ty'' + 7y = t .................................(1)
Together with the initial conditions:
y(1) = 1, y'(1) = 7
We want to determine the longest interval in which the given initial value problem is certain to have a unique twice-differentiable solution.
First, let us have the differential equation (1) in the form:
y'' + p(t)y' + q(t)y = r(t) ..................(2)
We do that by dividing (1) by t
So that
y''+ (7/t)y = 1 ....................................(3)
Comparing (3) with (2)
p(t) = 0
q(t) = 7/t
r(t) = 1
For t = 0, p(t) and r(t) are continuous, but q(t) = 7/0, which is undefined. Zero is certainly out of the required points.
In fact (-∞, 0) and (0,∞) are the points where p(t), q(t) and r(t) are continuous. But t = 1, which is contained in the initial conditions is found in (0,∞), and that makes it the correct interval.
So the largest interval containing 1 on which p(t), q(t) and r(t) are defined and continuous is (0,∞)
