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Section 6.1

Section 6.1. Cauchy-Euler Equation. THE CAUCHY-EULER EQUATION. Any linear differential equation of the from where a n , . . . , a 0 are constants, is said to be a Cauchy-Euler equation , or equidimensional equation . NOTE : The powers of x match the order of the derivative.

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Section 6.1

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  1. Section 6.1 Cauchy-Euler Equation

  2. THE CAUCHY-EULER EQUATION Any linear differential equation of the from where an, . . . , a0 are constants, is said to be a Cauchy-Euler equation, or equidimensional equation. NOTE: The powers of x match the order of the derivative.

  3. HOMOGENEOUS 2ND-ORDER CAUCHY-EULER EQUATION We will confine our attention to solving the homogeneous second-order equation. The solution of higher-order equations follows analogously. The nonhomogeneous equation can be solved by variation of parameters once the complimentary function, yc(x), is found.

  4. THE SOLUTION We try a solution of the form y = xm, where m must be determined. The first and second derivatives are, respectively, y′ = mxm − 1 and y″ = m(m − 1)xm − 2. Substituting into the differential equation, we find that xm is a solution of the equation whenever m is a solution of the auxiliary equation

  5. THREE CASES There are three cases to consider, depending on the roots of the auxiliary equation. Case I: Distinct Real Roots Case II: Repeated Real Roots Case III: Conjugate Complex Roots

  6. CASE I — DISTINCT REAL ROOTS Let m1 and m2 denote the real roots of the auxiliary equation where m1≠m2. Then form a fundamental solution set, and the general solution is

  7. CASE II — REPEATED REAL ROOTS Let m1 = m2 denote the real root of the auxiliary equation. Then we obtain one solution—namely, Using the formula from Section 4.2, we obtain the solution Then the general solution is

  8. CASE III — CONJUGATE COMPLEX ROOTS Let m1 = α + βi and m2 = α − βi, then the solution is Using Euler’s formula, we can obtain the fundamental set of solutions y1 = xα cos(βln x) and y2 = xα sin(βln x). Then the general solution is

  9. ALTERNATE METHOD OF SOLUTION Any Cauchy-Euler equation can be reduced to an equation with constant coefficients by means of the substitution x = et.

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