Reduce the system(D2 + 1)[x] − 2D[y] =

Meera Sunker

Meera Sunker

Answered question

2022-05-20

Reduce the system
(D2 + 1)[x] − 2D[y] = 2t
(2D − 1)[x] + (D − 2)[y] = 7.
to an equivalent triangular system of the form
P1(D)[y] = f1(t)
P2(D)[x] + P3(D)[y] = f2(t)
and solve.

Answer & Explanation

Vasquez

Vasquez

Expert2023-05-14Added 669 answers

To reduce the given system of differential equations to an equivalent triangular system, we need to manipulate the equations and express the derivatives in terms of a polynomial operator D. The triangular system will have the form:
P1(D)[y]=f1(t)
P2(D)[x]+P3(D)[y]=f2(t)
Let's solve the system step by step:
Step 1: Expand the differential operators
Expand the differential operators D2+1 and 2D1 in the first equation, and 2D1 and D2 in the second equation.
The given system is:
(D2+1)[x]2D[y]=2t(Equation 1)
(2D1)[x]+(D2)[y]=7(Equation 2)
Expanding the operators, we get:
(D·D+1)[x]2D[y]=2t
(2D1)[x]+(D2)[y]=7
Step 2: Rearrange the equations
Rearrange the equations so that the derivatives are written in terms of the polynomial operator D.
Equation 1 becomes:
D·(D[x])+x2D[y]=2t
Equation 2 becomes:
(2D1)[x]+(D2)[y]=7
Step 3: Identify the polynomial operators
By comparing the terms involving the derivatives, we can identify the polynomial operators:
P1(D)=D·(D[x])+1
P2(D)=2D1
P3(D)=D2
Step 4: Express the equations in the triangular form
Rewrite the equations in the desired triangular form using the polynomial operators:
P1(D)[y]=f1(t)
P2(D)[x]+P3(D)[y]=f2(t)
Substituting the identified operators and rearranging the terms, we have:
(D·(D[x])+1)[y]=2t
(2D1)[x]+(D2)[y]=7
Step 5: Simplify the expressions
Simplify the expressions further if possible.
(D2·x+x)[y]=2t
(2D1)[x]+(D2)[y]=7
Step 6: Solve the system
To solve the system, we first need to solve the first equation for x.
(D2·x+x)=2ty
Differentiate both sides with respect to t:
D(D2·x+x)=D(2ty)
Simplifying the equation, we have:
D3·x+Dx=2y
Now we have an equation relating x and its derivatives. We can substitute this equation into the second equation of the triangular system:
(2D1)(2y)+(D2)[y]=7
Expanding and simplifying the equation, we have:
4Dy2y+Dy2y=7
Combining like terms, we obtain:
(4D+D2y)(2+2yy)=7
To further simplify the equation, we multiply through by y to eliminate the denominators:
4D+D222y=7y
Rearranging the terms, we have:
D2+4D9y=2+9y
Now, the triangular system is in the form:
P1(D)[y]=f1(t)
P2(D)[x]+P3(D)[y]=f2(t)
where:
P1(D)=1
P2(D)=2D1
P3(D)=D2
f1(t)=2ty
f2(t)=2+9y
The system is now reduced to an equivalent triangular system. To solve for x and y, we can substitute the expression for x obtained from the first equation into the second equation.
Let's recap the triangular system:
1[y]=2ty
(2D1)[x]+(D2)[y]=2+9y
By substituting the expression for x into the second equation, we have:
(2D1)(2ty)+(D2)[y]=2+9y
Expanding the operators and simplifying the equation, we get:
4Dty2ty+Dy2y=2+9y
Combining like terms and rearranging, we obtain:
(4Dy+D)t(2y+2)=9y+2
Now we have a simplified equation relating t, y, and their derivatives. Solving this equation will give us the solution for the system.

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