In each of Problems 1 through 8, find the general differential equation. 1. y" - 2y' + y = 0

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can verify that the Wronskian of yı TO OUX (TE) (CE) #0 for t> 0. Upeni tatt ball Consequently, y, and y2 form a fundamental set of solutions of equation (33) for t > 0. Problems mont bonumine In each of Problems 1 through 8, find the general solution of the given differential equation. 10000 1. y" - 2y + y = 0 2. 9y" +6y' + y = 0 3. 4y" - 4y' - 3y = 0 4. y" - 2y +10y = 0 5. y" - 6y' +9y=0 6. 4y" +17y + 4y = 0 7. 16y" +24y' +9y = 0 8. 2y" +2y'+y=0 In each of Problems 9 through 11, solve the given initial value problem. Sketch the graph of the solution and describe its behavior for increasing t. 9. 9y" - 12y' + 4y = 0, 10. y"-6y' +9y = 0, 11. y" + 4y + 4y = 0, y(0) = 2, y'(0) = -1 y(0) = 0, y'(0) = 2 y(-1) = 2, y'(-1) = 1 12. Consider the following modification of the initial value problem in Example 2: y" - y' += 0, y(0) = 2, y'(0) = b. na Find the solution as a function of b, and then determine the critical value of b that separates solutions that remain positive for all t > 0 from those that eventually become negative. 3,-3/2 W[y₁, y2l(t) = 2 The Shosath 0=0x+1)+K opb N 13. Consider the initial value problem 4y" +4y' + y = 0, y(0) = 1, y'(0) = 2. (36) 1600 a. Solve the initial value problem and plot the solution. b. Determine the coordinates (tM, YM) of the maximum point. c. Change the second initial condition to y'(0) = b > 0 and find the solution as a function of b. d. Find the coordinates (tM, YM) of the maximum point in terms of b. Describe the dependence of tM and yM on b as b increases. 14. Consider the equation ay" + by' + cy= 0. If the roots of the corresponding characteristic equation are real, show that a solution to the differential equation either is everywhere zero or else can take on the value zero at most once. Problems 15 through 17 indicate other ways of finding the second solution when the characteristic equation has repeated roots. con In each of order to fir 15. a. Consider the equation y" + 2ay' + a²y = 0. Show that the roots of the characteristic equation are r₁ r₂ = -a so that one solution of the equation is eat. b. Use Abel's formula [equation (23) of Section 3.2] to show that the Wronskian of any two solutions of the given equation is W(t) = y₁(t) y₂(t) - y₁ (1) y₂(t) = c₁e-2at, 18. 12y 19. Fy 20. 12 21. xy where c₁ is a constant. c. Let y₁ (t) = eat and use the result of part b to obtain a differential equation satisfied by a second solution y2(t). By solving this equation, show that y2(t) = te-at. 22. X 23. T arises circu and 24. equ sol