8.2: El principio de superposición

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Ver tutorial en YouTube

Considere la oda lineal homogénea de segundo orden:

\[\ddot{x}+p(t) \dot{x}+q(t) x=0 \nonumber \]

y supongamos que\(x=X_{1}(t)\) y\(x=X_{2}(t)\) son soluciones a la Ecuación\ ref {8.4}. Consideramos una combinación lineal de\(X_{1}\) y\(X_{2}\) dejando

\[X(t)=c_{1} X_{1}(t)+c_{2} X_{2}(t), \nonumber \]

con\(c_{1}\) y\(c_{2}\) constantes. El principio de superposición establece que también\(x=X(t)\) es una solución de la Ecuación\ ref {8.4}. Para probarlo, calculamos

\[\begin{aligned} \ddot{X}+p \dot{X}+q X &=c_{1} \ddot{X}_{1}+c_{2} \ddot{X}_{2}+p\left(c_{1} \dot{X}_{1}+c_{2} \dot{X}_{2}\right)+q\left(c_{1} X_{1}+c_{2} X_{2}\right) \\ &=c_{1}\left(\ddot{X}_{1}+p \dot{X}_{1}+q X_{1}\right)+c_{2}\left(\ddot{X}_{2}+p \dot{X}_{2}+q X_{2}\right) \\ &=c_{1} \times 0+c_{2} \times 0 \\ &=0 \end{aligned} \nonumber \]

ya que\(X_{1}\) y\(X_{2}\) se suponía que eran soluciones de la Ecuación\ ref {8.4}. Por lo tanto, hemos demostrado que cualquier combinación lineal de soluciones a la oda lineal homogénea de segundo orden también es una solución.

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