In This Lesson Homogeneous with Constant Coefficients The Characteristic Equation Non-Homogeneous Equations Springs & Circuits Homogeneous with Constant Coefficients
Form: ay'' + by' + cy = 0
We "guess" y = eʳˣ because exponential functions reproduce themselves under differentiation. This converts the DE into the characteristic quadratic equation .
The Characteristic Equation Three cases based on the discriminant b² − 4ac:
Case 1: Two distinct real roots r₁, r₂: y = C₁e^(r₁x) + C₂e^(r₂x)Case 2: Repeated root r: y = (C₁ + C₂x)eʳˣCase 3: Complex roots α ± βi: y = eᵅˣ(C₁cos(βx) + C₂sin(βx))
Case 3 is the most physically interesting — it produces oscillation. The trigonometric functions appear through Euler's formula: eⁱᶿ = cos θ + i sin θ. The eigenvalue approach to systems x' = Ax yields the same three cases.
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 Example: y'' + 4y = 0 Characteristic: r² + 4 = 0 → r = ±2i (complex roots, α = 0, β = 2)
y = C₁cos(2x) + C₂sin(2x) — pure oscillation!
Non-Homogeneous Equations 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
ay'' + by' + cy = g(x)
Methods for finding yₚ:
Undetermined coefficients: Guess yₚ based on g(x). If g = polynomial, guess polynomial; if g = eᵃˣ, guess Aeᵃˣ; if g = sin/cos, guess A·cos + B·sinVariation of parameters: More general but requires integration . Works for any g(x)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 Springs & Circuits 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
Spring-mass: my'' + by' + ky = F(t)
Undamped (b = 0): Pure oscillation at natural frequency ω₀ = √(k/m)Underdamped (b² < 4mk): Decaying oscillation — connects to wave applications Critically damped (b² = 4mk): Fastest return without oscillationOverdamped (b² > 4mk): Slow exponential decay Resonance occurs when forcing frequency matches natural frequency — amplitude grows without bound (in the undamped case). This explains why soldiers break step on bridges and why opera singers can shatter glass. The
Laplace transform method handles these problems elegantly.