To solve the differential equation 14 y” + y’ + 4y = x^2 using the method of undetermined coefficients, we first need to determine the complementary solution and a particular solution.
Step 1: Find the Complementary Solution (yc)
The characteristic equation is derived from the homogeneous part of the differential equation:
14r2 + r + 4 = 0
Using the quadratic formula, r = (-b ± √(b² - 4ac)) / 2a, where a = 14, b = 1, and c = 4, we compute:
r = ( -1 ± √(1² – 4 * 14 * 4) ) / (2 * 14)
This simplifies to:
r = ( -1 ± √(-223) ) / 28
Since the discriminant is negative, we have complex roots:
r = -1/28 ± (√223 / 28)i
The complementary solution is then given by:
yc = e^(-1/28)x (C1 cos(√223/28 * x) + C2 sin(√223/28 * x))
Step 2: Find the Particular Solution (yp)
Next, we find a particular solution by assuming a form that fits the non-homogeneous part x². Since the degree is 2, we take:
yp = Ax² + Bx + C
Now we need the first and second derivatives:
yp‘ = 2Ax + B
yp” = 2A
Substituting yp, yp‘, and yp” into the differential equation:
14(2A) + (2Ax + B) + 4(Ax² + Bx + C) = x²
Grouping like terms:
(14*2A + 4A)x² + (2A + 4B)x + (14*2A + B + 4C) = x²
This yields the system of equations:
- 4A + 28A = 1 (Coefficient of x²)
- 2A + 4B = 0 (Coefficient of x)
- 14*2A + B + 4C = 0 (Constant term)
Simplifying these equations gives:
- 32A = 1 ⇒ A = 1/32
- 2(1/32) + 4B = 0 ⇒ B = -1/64
- 28(1/32) – 1/64 + 4C = 0 ⇒ C = -7/64
Thus, the particular solution is:
yp = (1/32)x² – (1/64)x – (7/64)
Step 3: General Solution
The general solution is the sum of the complementary and particular solutions:
y = yc + yp
y = e^(-1/28)x (C1 cos(√223/28 * x) + C2 sin(√223/28 * x)) + (1/32)x² – (1/64)x – (7/64)
This completes the solution of the differential equation using the method of undetermined coefficients.