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Deck 16: Second Order Differential Equations

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Question
Identify the general solution of the the differential equation <strong>Identify the general solution of the the differential equation .</strong> A) B) C) D) <div style=padding-top: 35px> .

A) <strong>Identify the general solution of the the differential equation .</strong> A) B) C) D) <div style=padding-top: 35px>
B) <strong>Identify the general solution of the the differential equation .</strong> A) B) C) D) <div style=padding-top: 35px>
C) <strong>Identify the general solution of the the differential equation .</strong> A) B) C) D) <div style=padding-top: 35px>
D) <strong>Identify the general solution of the the differential equation .</strong> A) B) C) D) <div style=padding-top: 35px>
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Question
Solve the initial value problem <strong>Solve the initial value problem , .</strong> A) B) C) D) <div style=padding-top: 35px> , <strong>Solve the initial value problem , .</strong> A) B) C) D) <div style=padding-top: 35px> .

A) <strong>Solve the initial value problem , .</strong> A) B) C) D) <div style=padding-top: 35px>
B) <strong>Solve the initial value problem , .</strong> A) B) C) D) <div style=padding-top: 35px>
C) <strong>Solve the initial value problem , .</strong> A) B) C) D) <div style=padding-top: 35px>
D) <strong>Solve the initial value problem , .</strong> A) B) C) D) <div style=padding-top: 35px>
Question
Identify the general solution of the the differential equation <strong>Identify the general solution of the the differential equation .</strong> A) B) C) D) <div style=padding-top: 35px> .

A) <strong>Identify the general solution of the the differential equation .</strong> A) B) C) D) <div style=padding-top: 35px>
B) <strong>Identify the general solution of the the differential equation .</strong> A) B) C) D) <div style=padding-top: 35px>
C) <strong>Identify the general solution of the the differential equation .</strong> A) B) C) D) <div style=padding-top: 35px>
D) <strong>Identify the general solution of the the differential equation .</strong> A) B) C) D) <div style=padding-top: 35px>
Question
Solve the initial value problem. Solve the initial value problem. <div style=padding-top: 35px>
Question
A 0.15 kg mass hangs on a spring with a 2 N m-1 force constant and its motion is damped proportional to its velocity with proportionality constant 0.2 kg s-1. If the system is subjected to an external variable-frequency vibration described as <strong>A 0.15 kg mass hangs on a spring with a 2 N m<sup>-1</sup> force constant and its motion is damped proportional to its velocity with proportionality constant 0.2 kg s<sup>-1</sup>. If the system is subjected to an external variable-frequency vibration described as newtons, what will be the amplitude of the steady-state oscillation?</strong> A) 2.03 m B) 4.14 m C) 0.12 m D) 0.00 m <div style=padding-top: 35px> newtons, what will be the amplitude of the steady-state oscillation?

A) 2.03 m
B) 4.14 m
C) 0.12 m
D) 0.00 m
Question
Consider solutions to the second order differential equation <strong>Consider solutions to the second order differential equation in which m, c, and k are positive constants. Which of the following pairs of graphs might correspond to the sets of constants m = 1.00, c = 0.80, and k = 1.20 (blue graph), and m = 1.00, c = 0.08, and k = 1.20 (red graph) ?</strong> A) B) C) D) <div style=padding-top: 35px> in which m, c, and k are positive constants. Which of the following pairs of graphs might correspond to the sets of constants m = 1.00, c = 0.80, and k = 1.20 (blue graph), and m = 1.00, c = 0.08, and k = 1.20 (red graph) ?

A) <strong>Consider solutions to the second order differential equation in which m, c, and k are positive constants. Which of the following pairs of graphs might correspond to the sets of constants m = 1.00, c = 0.80, and k = 1.20 (blue graph), and m = 1.00, c = 0.08, and k = 1.20 (red graph) ?</strong> A) B) C) D) <div style=padding-top: 35px> <strong>Consider solutions to the second order differential equation in which m, c, and k are positive constants. Which of the following pairs of graphs might correspond to the sets of constants m = 1.00, c = 0.80, and k = 1.20 (blue graph), and m = 1.00, c = 0.08, and k = 1.20 (red graph) ?</strong> A) B) C) D) <div style=padding-top: 35px>
B) <strong>Consider solutions to the second order differential equation in which m, c, and k are positive constants. Which of the following pairs of graphs might correspond to the sets of constants m = 1.00, c = 0.80, and k = 1.20 (blue graph), and m = 1.00, c = 0.08, and k = 1.20 (red graph) ?</strong> A) B) C) D) <div style=padding-top: 35px> <strong>Consider solutions to the second order differential equation in which m, c, and k are positive constants. Which of the following pairs of graphs might correspond to the sets of constants m = 1.00, c = 0.80, and k = 1.20 (blue graph), and m = 1.00, c = 0.08, and k = 1.20 (red graph) ?</strong> A) B) C) D) <div style=padding-top: 35px>
C) <strong>Consider solutions to the second order differential equation in which m, c, and k are positive constants. Which of the following pairs of graphs might correspond to the sets of constants m = 1.00, c = 0.80, and k = 1.20 (blue graph), and m = 1.00, c = 0.08, and k = 1.20 (red graph) ?</strong> A) B) C) D) <div style=padding-top: 35px> <strong>Consider solutions to the second order differential equation in which m, c, and k are positive constants. Which of the following pairs of graphs might correspond to the sets of constants m = 1.00, c = 0.80, and k = 1.20 (blue graph), and m = 1.00, c = 0.08, and k = 1.20 (red graph) ?</strong> A) B) C) D) <div style=padding-top: 35px>
D) <strong>Consider solutions to the second order differential equation in which m, c, and k are positive constants. Which of the following pairs of graphs might correspond to the sets of constants m = 1.00, c = 0.80, and k = 1.20 (blue graph), and m = 1.00, c = 0.08, and k = 1.20 (red graph) ?</strong> A) B) C) D) <div style=padding-top: 35px> <strong>Consider solutions to the second order differential equation in which m, c, and k are positive constants. Which of the following pairs of graphs might correspond to the sets of constants m = 1.00, c = 0.80, and k = 1.20 (blue graph), and m = 1.00, c = 0.08, and k = 1.20 (red graph) ?</strong> A) B) C) D) <div style=padding-top: 35px>
Question
A spring is stretched 5 cm by a 1-kg mass. The mass is set in motion from its equilibrium position with an upward velocity of 2 m/s. The damping constant equals A spring is stretched 5 cm by a 1-kg mass. The mass is set in motion from its equilibrium position with an upward velocity of 2 m/s. The damping constant equals Find an equation for the position of the mass at any time t.<div style=padding-top: 35px> Find an equation for the position of the mass at any time t.
Question
Determine the form of a particular solution of the equation. <strong>Determine the form of a particular solution of the equation. </strong> A) B) C) D) <div style=padding-top: 35px>

A) <strong>Determine the form of a particular solution of the equation. </strong> A) B) C) D) <div style=padding-top: 35px>
B) <strong>Determine the form of a particular solution of the equation. </strong> A) B) C) D) <div style=padding-top: 35px>
C) <strong>Determine the form of a particular solution of the equation. </strong> A) B) C) D) <div style=padding-top: 35px>
D) <strong>Determine the form of a particular solution of the equation. </strong> A) B) C) D) <div style=padding-top: 35px>
Question
Identify the form of a particular solution to the equation <strong>Identify the form of a particular solution to the equation .</strong> A) B) C) D) <div style=padding-top: 35px> .

A) <strong>Identify the form of a particular solution to the equation .</strong> A) B) C) D) <div style=padding-top: 35px>
B) <strong>Identify the form of a particular solution to the equation .</strong> A) B) C) D) <div style=padding-top: 35px>
C) <strong>Identify the form of a particular solution to the equation .</strong> A) B) C) D) <div style=padding-top: 35px>
D) <strong>Identify the form of a particular solution to the equation .</strong> A) B) C) D) <div style=padding-top: 35px>
Question
Find the general solution of <strong>Find the general solution of , given the particular solution .</strong> A) B) C) D) <div style=padding-top: 35px> , given the particular solution <strong>Find the general solution of , given the particular solution .</strong> A) B) C) D) <div style=padding-top: 35px> .

A) <strong>Find the general solution of , given the particular solution .</strong> A) B) C) D) <div style=padding-top: 35px>
B) <strong>Find the general solution of , given the particular solution .</strong> A) B) C) D) <div style=padding-top: 35px>
C) <strong>Find the general solution of , given the particular solution .</strong> A) B) C) D) <div style=padding-top: 35px>
D) <strong>Find the general solution of , given the particular solution .</strong> A) B) C) D) <div style=padding-top: 35px>
Question
Solve the initial value problem <strong>Solve the initial value problem , .</strong> A) B) C) D) <div style=padding-top: 35px> , <strong>Solve the initial value problem , .</strong> A) B) C) D) <div style=padding-top: 35px> .

A) <strong>Solve the initial value problem , .</strong> A) B) C) D) <div style=padding-top: 35px>
B) <strong>Solve the initial value problem , .</strong> A) B) C) D) <div style=padding-top: 35px>
C) <strong>Solve the initial value problem , .</strong> A) B) C) D) <div style=padding-top: 35px>
D) <strong>Solve the initial value problem , .</strong> A) B) C) D) <div style=padding-top: 35px>
Question
A certain spring is at rest when stretched 0.392 m by a 2.0 kg mass. Which function describes the motion of the mass if it is pulled down 0.25 m and released without imparting any initial velocity at time t = 0? Other helpful information: the motion is not damped; use 9.8 m s-2 as the acceleration due to gravity; and consider the zero position to be the rest position of the spring with the mass attached, and downward motion defines the positive x direction.

A) <strong>A certain spring is at rest when stretched 0.392 m by a 2.0 kg mass. Which function describes the motion of the mass if it is pulled down 0.25 m and released without imparting any initial velocity at time t = 0? Other helpful information: the motion is not damped; use 9.8 m s<sup>-2</sup> as the acceleration due to gravity; and consider the zero position to be the rest position of the spring with the mass attached, and downward motion defines the positive x direction.</strong> A) B) C) D) <div style=padding-top: 35px>
B) <strong>A certain spring is at rest when stretched 0.392 m by a 2.0 kg mass. Which function describes the motion of the mass if it is pulled down 0.25 m and released without imparting any initial velocity at time t = 0? Other helpful information: the motion is not damped; use 9.8 m s<sup>-2</sup> as the acceleration due to gravity; and consider the zero position to be the rest position of the spring with the mass attached, and downward motion defines the positive x direction.</strong> A) B) C) D) <div style=padding-top: 35px>
C) <strong>A certain spring is at rest when stretched 0.392 m by a 2.0 kg mass. Which function describes the motion of the mass if it is pulled down 0.25 m and released without imparting any initial velocity at time t = 0? Other helpful information: the motion is not damped; use 9.8 m s<sup>-2</sup> as the acceleration due to gravity; and consider the zero position to be the rest position of the spring with the mass attached, and downward motion defines the positive x direction.</strong> A) B) C) D) <div style=padding-top: 35px>
D) <strong>A certain spring is at rest when stretched 0.392 m by a 2.0 kg mass. Which function describes the motion of the mass if it is pulled down 0.25 m and released without imparting any initial velocity at time t = 0? Other helpful information: the motion is not damped; use 9.8 m s<sup>-2</sup> as the acceleration due to gravity; and consider the zero position to be the rest position of the spring with the mass attached, and downward motion defines the positive x direction.</strong> A) B) C) D) <div style=padding-top: 35px>
Question
Identify the form of a particular solution to the equation <strong>Identify the form of a particular solution to the equation .</strong> A) B) C) D) <div style=padding-top: 35px> .

A) <strong>Identify the form of a particular solution to the equation .</strong> A) B) C) D) <div style=padding-top: 35px>
B) <strong>Identify the form of a particular solution to the equation .</strong> A) B) C) D) <div style=padding-top: 35px>
C) <strong>Identify the form of a particular solution to the equation .</strong> A) B) C) D) <div style=padding-top: 35px>
D) <strong>Identify the form of a particular solution to the equation .</strong> A) B) C) D) <div style=padding-top: 35px>
Question
Find the general solution of <strong>Find the general solution of , given the particular solution .</strong> A) B) C) D) <div style=padding-top: 35px> , given the particular solution <strong>Find the general solution of , given the particular solution .</strong> A) B) C) D) <div style=padding-top: 35px> .

A) <strong>Find the general solution of , given the particular solution .</strong> A) B) C) D) <div style=padding-top: 35px>
B) <strong>Find the general solution of , given the particular solution .</strong> A) B) C) D) <div style=padding-top: 35px>
C) <strong>Find the general solution of , given the particular solution .</strong> A) B) C) D) <div style=padding-top: 35px>
D) <strong>Find the general solution of , given the particular solution .</strong> A) B) C) D) <div style=padding-top: 35px>
Question
A 2.0 kg mass hangs on a spring with a 1.1 newton/meter force constant and its motion is not damped. If the system is subjected to an external variable-frequency vibration described as <strong>A 2.0 kg mass hangs on a spring with a 1.1 newton/meter force constant and its motion is not damped. If the system is subjected to an external variable-frequency vibration described as newtons, at what frequency, , will the external vibration and the spring system be in resonance?</strong> A) 0.55 s<sup>-1</sup> B) 0.74 s<sup>-1</sup> C) 1.82 s<sup>-1</sup> D) 1.35 s<sup>-1</sup> <div style=padding-top: 35px> newtons, at what frequency, <strong>A 2.0 kg mass hangs on a spring with a 1.1 newton/meter force constant and its motion is not damped. If the system is subjected to an external variable-frequency vibration described as newtons, at what frequency, , will the external vibration and the spring system be in resonance?</strong> A) 0.55 s<sup>-1</sup> B) 0.74 s<sup>-1</sup> C) 1.82 s<sup>-1</sup> D) 1.35 s<sup>-1</sup> <div style=padding-top: 35px> , will the external vibration and the spring system be in resonance?

A) 0.55 s-1
B) 0.74 s-1
C) 1.82 s-1
D) 1.35 s-1
Question
Solve the initial value problem <strong>Solve the initial value problem , .</strong> A) B) C) D) <div style=padding-top: 35px> , <strong>Solve the initial value problem , .</strong> A) B) C) D) <div style=padding-top: 35px> .

A) <strong>Solve the initial value problem , .</strong> A) B) C) D) <div style=padding-top: 35px>
B) <strong>Solve the initial value problem , .</strong> A) B) C) D) <div style=padding-top: 35px>
C) <strong>Solve the initial value problem , .</strong> A) B) C) D) <div style=padding-top: 35px>
D) <strong>Solve the initial value problem , .</strong> A) B) C) D) <div style=padding-top: 35px>
Question
Find the general solution of the equation <strong>Find the general solution of the equation .</strong> A) B) C) D) <div style=padding-top: 35px> .

A) <strong>Find the general solution of the equation .</strong> A) B) C) D) <div style=padding-top: 35px>
B) <strong>Find the general solution of the equation .</strong> A) B) C) D) <div style=padding-top: 35px>
C) <strong>Find the general solution of the equation .</strong> A) B) C) D) <div style=padding-top: 35px>
D) <strong>Find the general solution of the equation .</strong> A) B) C) D) <div style=padding-top: 35px>
Question
Find the general solution of the differential equation. <strong>Find the general solution of the differential equation. </strong> A) B) C) D) <div style=padding-top: 35px>

A) <strong>Find the general solution of the differential equation. </strong> A) B) C) D) <div style=padding-top: 35px>
B) <strong>Find the general solution of the differential equation. </strong> A) B) C) D) <div style=padding-top: 35px>
C) <strong>Find the general solution of the differential equation. </strong> A) B) C) D) <div style=padding-top: 35px>
D) <strong>Find the general solution of the differential equation. </strong> A) B) C) D) <div style=padding-top: 35px>
Question
Identify the general solution of the the differential equation <strong>Identify the general solution of the the differential equation .</strong> A) B) C) D) <div style=padding-top: 35px> .

A) <strong>Identify the general solution of the the differential equation .</strong> A) B) C) D) <div style=padding-top: 35px>
B) <strong>Identify the general solution of the the differential equation .</strong> A) B) C) D) <div style=padding-top: 35px>
C) <strong>Identify the general solution of the the differential equation .</strong> A) B) C) D) <div style=padding-top: 35px>
D) <strong>Identify the general solution of the the differential equation .</strong> A) B) C) D) <div style=padding-top: 35px>
Question
For For find the steady-state solution and identify its amplitude and phase shift.<div style=padding-top: 35px> find the steady-state solution and identify its amplitude and phase shift.
Question
A series circuit has a 0.15 henry inductor, a 350 ohm resistor, and a 0.00001 farad capacitor. There is an initial charge of 0.000001 coulombs, there is no initial current, and there is an applied voltage which is described as <strong>A series circuit has a 0.15 henry inductor, a 350 ohm resistor, and a 0.00001 farad capacitor. There is an initial charge of 0.000001 coulombs, there is no initial current, and there is an applied voltage which is described as . Identify the solution to the differential equation that describes the charge on the capacitor as a function of time.</strong> A) B) C) D) <div style=padding-top: 35px> . Identify the solution to the differential equation that describes the charge on the capacitor as a function of time.

A) <strong>A series circuit has a 0.15 henry inductor, a 350 ohm resistor, and a 0.00001 farad capacitor. There is an initial charge of 0.000001 coulombs, there is no initial current, and there is an applied voltage which is described as . Identify the solution to the differential equation that describes the charge on the capacitor as a function of time.</strong> A) B) C) D) <div style=padding-top: 35px>
B) <strong>A series circuit has a 0.15 henry inductor, a 350 ohm resistor, and a 0.00001 farad capacitor. There is an initial charge of 0.000001 coulombs, there is no initial current, and there is an applied voltage which is described as . Identify the solution to the differential equation that describes the charge on the capacitor as a function of time.</strong> A) B) C) D) <div style=padding-top: 35px>
C) <strong>A series circuit has a 0.15 henry inductor, a 350 ohm resistor, and a 0.00001 farad capacitor. There is an initial charge of 0.000001 coulombs, there is no initial current, and there is an applied voltage which is described as . Identify the solution to the differential equation that describes the charge on the capacitor as a function of time.</strong> A) B) C) D) <div style=padding-top: 35px>
D) <strong>A series circuit has a 0.15 henry inductor, a 350 ohm resistor, and a 0.00001 farad capacitor. There is an initial charge of 0.000001 coulombs, there is no initial current, and there is an applied voltage which is described as . Identify the solution to the differential equation that describes the charge on the capacitor as a function of time.</strong> A) B) C) D) <div style=padding-top: 35px>
Question
A second order differential equaiton can be arranged to the form <strong>A second order differential equaiton can be arranged to the form , and one can find the third and higher derivatives of y by simply differentiating this equation. Since a Taylor series expansion of a function y(x) is , one can differentiate the rearranged second order differential equation to evaluate coefficients of the Taylor polynomial, if one is either given or can solve for the initial condition y(0) and y'(0). What does the fourth-degree Taylor polynomial look like for the solution to the equation if the initial conditions are ?</strong> A) B) C) D) <div style=padding-top: 35px> , and one can find the third and higher derivatives of y by simply differentiating this equation. Since a Taylor series expansion of a function y(x) is <strong>A second order differential equaiton can be arranged to the form , and one can find the third and higher derivatives of y by simply differentiating this equation. Since a Taylor series expansion of a function y(x) is , one can differentiate the rearranged second order differential equation to evaluate coefficients of the Taylor polynomial, if one is either given or can solve for the initial condition y(0) and y'(0). What does the fourth-degree Taylor polynomial look like for the solution to the equation if the initial conditions are ?</strong> A) B) C) D) <div style=padding-top: 35px> , one can differentiate the rearranged second order differential equation to evaluate coefficients of the Taylor polynomial, if one is either given or can solve for the initial condition y(0) and y'(0). What does the fourth-degree Taylor polynomial look like for the solution to the equation <strong>A second order differential equaiton can be arranged to the form , and one can find the third and higher derivatives of y by simply differentiating this equation. Since a Taylor series expansion of a function y(x) is , one can differentiate the rearranged second order differential equation to evaluate coefficients of the Taylor polynomial, if one is either given or can solve for the initial condition y(0) and y'(0). What does the fourth-degree Taylor polynomial look like for the solution to the equation if the initial conditions are ?</strong> A) B) C) D) <div style=padding-top: 35px> if the initial conditions are <strong>A second order differential equaiton can be arranged to the form , and one can find the third and higher derivatives of y by simply differentiating this equation. Since a Taylor series expansion of a function y(x) is , one can differentiate the rearranged second order differential equation to evaluate coefficients of the Taylor polynomial, if one is either given or can solve for the initial condition y(0) and y'(0). What does the fourth-degree Taylor polynomial look like for the solution to the equation if the initial conditions are ?</strong> A) B) C) D) <div style=padding-top: 35px> ?

A) <strong>A second order differential equaiton can be arranged to the form , and one can find the third and higher derivatives of y by simply differentiating this equation. Since a Taylor series expansion of a function y(x) is , one can differentiate the rearranged second order differential equation to evaluate coefficients of the Taylor polynomial, if one is either given or can solve for the initial condition y(0) and y'(0). What does the fourth-degree Taylor polynomial look like for the solution to the equation if the initial conditions are ?</strong> A) B) C) D) <div style=padding-top: 35px>
B) <strong>A second order differential equaiton can be arranged to the form , and one can find the third and higher derivatives of y by simply differentiating this equation. Since a Taylor series expansion of a function y(x) is , one can differentiate the rearranged second order differential equation to evaluate coefficients of the Taylor polynomial, if one is either given or can solve for the initial condition y(0) and y'(0). What does the fourth-degree Taylor polynomial look like for the solution to the equation if the initial conditions are ?</strong> A) B) C) D) <div style=padding-top: 35px>
C) <strong>A second order differential equaiton can be arranged to the form , and one can find the third and higher derivatives of y by simply differentiating this equation. Since a Taylor series expansion of a function y(x) is , one can differentiate the rearranged second order differential equation to evaluate coefficients of the Taylor polynomial, if one is either given or can solve for the initial condition y(0) and y'(0). What does the fourth-degree Taylor polynomial look like for the solution to the equation if the initial conditions are ?</strong> A) B) C) D) <div style=padding-top: 35px>
D) <strong>A second order differential equaiton can be arranged to the form , and one can find the third and higher derivatives of y by simply differentiating this equation. Since a Taylor series expansion of a function y(x) is , one can differentiate the rearranged second order differential equation to evaluate coefficients of the Taylor polynomial, if one is either given or can solve for the initial condition y(0) and y'(0). What does the fourth-degree Taylor polynomial look like for the solution to the equation if the initial conditions are ?</strong> A) B) C) D) <div style=padding-top: 35px>
Question
Find the recurrence relation for the general power series solution <strong>Find the recurrence relation for the general power series solution to the second order equation .</strong> A) B) C) D) <div style=padding-top: 35px> to the second order equation <strong>Find the recurrence relation for the general power series solution to the second order equation .</strong> A) B) C) D) <div style=padding-top: 35px> .

A) <strong>Find the recurrence relation for the general power series solution to the second order equation .</strong> A) B) C) D) <div style=padding-top: 35px>
B) <strong>Find the recurrence relation for the general power series solution to the second order equation .</strong> A) B) C) D) <div style=padding-top: 35px>
C) <strong>Find the recurrence relation for the general power series solution to the second order equation .</strong> A) B) C) D) <div style=padding-top: 35px>
D) <strong>Find the recurrence relation for the general power series solution to the second order equation .</strong> A) B) C) D) <div style=padding-top: 35px>
Question
Suppose that the charge in a circuit satisfies the equation <strong>Suppose that the charge in a circuit satisfies the equation Find the gain of the circuit.</strong> A) B) C) D) <div style=padding-top: 35px> Find the gain of the circuit.

A) <strong>Suppose that the charge in a circuit satisfies the equation Find the gain of the circuit.</strong> A) B) C) D) <div style=padding-top: 35px>
B) <strong>Suppose that the charge in a circuit satisfies the equation Find the gain of the circuit.</strong> A) B) C) D) <div style=padding-top: 35px>
C) <strong>Suppose that the charge in a circuit satisfies the equation Find the gain of the circuit.</strong> A) B) C) D) <div style=padding-top: 35px>
D) <strong>Suppose that the charge in a circuit satisfies the equation Find the gain of the circuit.</strong> A) B) C) D) <div style=padding-top: 35px>
Question
Identify the radius of convergence of the power series solutions about x = 0 of <strong>Identify the radius of convergence of the power series solutions about x = 0 of .</strong> A) B) C) D) <div style=padding-top: 35px> .

A) <strong>Identify the radius of convergence of the power series solutions about x = 0 of .</strong> A) B) C) D) <div style=padding-top: 35px>
B) <strong>Identify the radius of convergence of the power series solutions about x = 0 of .</strong> A) B) C) D) <div style=padding-top: 35px>
C) <strong>Identify the radius of convergence of the power series solutions about x = 0 of .</strong> A) B) C) D) <div style=padding-top: 35px>
D) <strong>Identify the radius of convergence of the power series solutions about x = 0 of .</strong> A) B) C) D) <div style=padding-top: 35px>
Question
Identify the radius of convergence of the power series solutions about x = 0 of <strong>Identify the radius of convergence of the power series solutions about x = 0 of .</strong> A) R = 0 B) C) R = D) R = 4 <div style=padding-top: 35px> .

A) R = 0
B) <strong>Identify the radius of convergence of the power series solutions about x = 0 of .</strong> A) R = 0 B) C) R = D) R = 4 <div style=padding-top: 35px>
C) R = <strong>Identify the radius of convergence of the power series solutions about x = 0 of .</strong> A) R = 0 B) C) R = D) R = 4 <div style=padding-top: 35px>
D) R = 4
Question
Solve the initial value problem <strong>Solve the initial value problem , .</strong> A) B) C) D) <div style=padding-top: 35px> , <strong>Solve the initial value problem , .</strong> A) B) C) D) <div style=padding-top: 35px> .

A) <strong>Solve the initial value problem , .</strong> A) B) C) D) <div style=padding-top: 35px>
B) <strong>Solve the initial value problem , .</strong> A) B) C) D) <div style=padding-top: 35px>
C) <strong>Solve the initial value problem , .</strong> A) B) C) D) <div style=padding-top: 35px>
D) <strong>Solve the initial value problem , .</strong> A) B) C) D) <div style=padding-top: 35px>
Question
For a pendulum of weight 4 pounds, length 0.75 ft, damping constant <strong>For a pendulum of weight 4 pounds, length 0.75 ft, damping constant and forcing function find the amplitude and period of the steady-state motion. [The acceleration due to gravity is 32 ft s<sup>-2</sup>.]</strong> A) amplitude: 0.500 ft; period: 1.738 rad B) amplitude: 0.250 ft; period: 0.869 rad C) amplitude: 0.299 ft; period: 0.524 rad D) amplitude: 0.598 ft; period: 1.047 rad <div style=padding-top: 35px> and forcing function <strong>For a pendulum of weight 4 pounds, length 0.75 ft, damping constant and forcing function find the amplitude and period of the steady-state motion. [The acceleration due to gravity is 32 ft s<sup>-2</sup>.]</strong> A) amplitude: 0.500 ft; period: 1.738 rad B) amplitude: 0.250 ft; period: 0.869 rad C) amplitude: 0.299 ft; period: 0.524 rad D) amplitude: 0.598 ft; period: 1.047 rad <div style=padding-top: 35px> find the amplitude and period of the steady-state motion. [The acceleration due to gravity is 32 ft s-2.]

A) amplitude: 0.500 ft; period: 1.738 rad
B) amplitude: 0.250 ft; period: 0.869 rad
C) amplitude: 0.299 ft; period: 0.524 rad
D) amplitude: 0.598 ft; period: 1.047 rad
Question
A series circuit has a 0.2 henry inductor, a 490 ohm resistor, and a 0.000004 farad capacitor. There is an applied voltage which is described as <strong>A series circuit has a 0.2 henry inductor, a 490 ohm resistor, and a 0.000004 farad capacitor. There is an applied voltage which is described as . Identify the general solution to the differential equation that describes the charge on the capacitor as a function of time.</strong> A) B) C) D) <div style=padding-top: 35px> . Identify the general solution to the differential equation that describes the charge on the capacitor as a function of time.

A) <strong>A series circuit has a 0.2 henry inductor, a 490 ohm resistor, and a 0.000004 farad capacitor. There is an applied voltage which is described as . Identify the general solution to the differential equation that describes the charge on the capacitor as a function of time.</strong> A) B) C) D) <div style=padding-top: 35px>
B) <strong>A series circuit has a 0.2 henry inductor, a 490 ohm resistor, and a 0.000004 farad capacitor. There is an applied voltage which is described as . Identify the general solution to the differential equation that describes the charge on the capacitor as a function of time.</strong> A) B) C) D) <div style=padding-top: 35px>
C) <strong>A series circuit has a 0.2 henry inductor, a 490 ohm resistor, and a 0.000004 farad capacitor. There is an applied voltage which is described as . Identify the general solution to the differential equation that describes the charge on the capacitor as a function of time.</strong> A) B) C) D) <div style=padding-top: 35px>
D) <strong>A series circuit has a 0.2 henry inductor, a 490 ohm resistor, and a 0.000004 farad capacitor. There is an applied voltage which is described as . Identify the general solution to the differential equation that describes the charge on the capacitor as a function of time.</strong> A) B) C) D) <div style=padding-top: 35px>
Question
A series circuit has a 0.1 henry inductor, a 330 ohm resistor, and a 0.000009 farad capacitor. There is an initial charge of 0.000002 coulombs, there is no initial current, and there is an applied voltage which is described as <strong>A series circuit has a 0.1 henry inductor, a 330 ohm resistor, and a 0.000009 farad capacitor. There is an initial charge of 0.000002 coulombs, there is no initial current, and there is an applied voltage which is described as . Identify the solution to the differential equation that describes the charge on the capacitor as a function of time.</strong> A) B) C) D) <div style=padding-top: 35px> . Identify the solution to the differential equation that describes the charge on the capacitor as a function of time.

A) <strong>A series circuit has a 0.1 henry inductor, a 330 ohm resistor, and a 0.000009 farad capacitor. There is an initial charge of 0.000002 coulombs, there is no initial current, and there is an applied voltage which is described as . Identify the solution to the differential equation that describes the charge on the capacitor as a function of time.</strong> A) B) C) D) <div style=padding-top: 35px>
B) <strong>A series circuit has a 0.1 henry inductor, a 330 ohm resistor, and a 0.000009 farad capacitor. There is an initial charge of 0.000002 coulombs, there is no initial current, and there is an applied voltage which is described as . Identify the solution to the differential equation that describes the charge on the capacitor as a function of time.</strong> A) B) C) D) <div style=padding-top: 35px>
C) <strong>A series circuit has a 0.1 henry inductor, a 330 ohm resistor, and a 0.000009 farad capacitor. There is an initial charge of 0.000002 coulombs, there is no initial current, and there is an applied voltage which is described as . Identify the solution to the differential equation that describes the charge on the capacitor as a function of time.</strong> A) B) C) D) <div style=padding-top: 35px>
D) <strong>A series circuit has a 0.1 henry inductor, a 330 ohm resistor, and a 0.000009 farad capacitor. There is an initial charge of 0.000002 coulombs, there is no initial current, and there is an applied voltage which is described as . Identify the solution to the differential equation that describes the charge on the capacitor as a function of time.</strong> A) B) C) D) <div style=padding-top: 35px>
Question
Identify the pair of graphs that correspond most closely to the solutions of <strong>Identify the pair of graphs that correspond most closely to the solutions of with , respectively. [The function y(t) is plotted on the vertical axes and t is plotted on the horizontal axes.]</strong> A) B) C) D) <div style=padding-top: 35px> with <strong>Identify the pair of graphs that correspond most closely to the solutions of with , respectively. [The function y(t) is plotted on the vertical axes and t is plotted on the horizontal axes.]</strong> A) B) C) D) <div style=padding-top: 35px> , respectively. [The function y(t) is plotted on the vertical axes and t is plotted on the horizontal axes.]

A) <strong>Identify the pair of graphs that correspond most closely to the solutions of with , respectively. [The function y(t) is plotted on the vertical axes and t is plotted on the horizontal axes.]</strong> A) B) C) D) <div style=padding-top: 35px> <strong>Identify the pair of graphs that correspond most closely to the solutions of with , respectively. [The function y(t) is plotted on the vertical axes and t is plotted on the horizontal axes.]</strong> A) B) C) D) <div style=padding-top: 35px>
B) <strong>Identify the pair of graphs that correspond most closely to the solutions of with , respectively. [The function y(t) is plotted on the vertical axes and t is plotted on the horizontal axes.]</strong> A) B) C) D) <div style=padding-top: 35px> <strong>Identify the pair of graphs that correspond most closely to the solutions of with , respectively. [The function y(t) is plotted on the vertical axes and t is plotted on the horizontal axes.]</strong> A) B) C) D) <div style=padding-top: 35px>
C) <strong>Identify the pair of graphs that correspond most closely to the solutions of with , respectively. [The function y(t) is plotted on the vertical axes and t is plotted on the horizontal axes.]</strong> A) B) C) D) <div style=padding-top: 35px> <strong>Identify the pair of graphs that correspond most closely to the solutions of with , respectively. [The function y(t) is plotted on the vertical axes and t is plotted on the horizontal axes.]</strong> A) B) C) D) <div style=padding-top: 35px>
D) <strong>Identify the pair of graphs that correspond most closely to the solutions of with , respectively. [The function y(t) is plotted on the vertical axes and t is plotted on the horizontal axes.]</strong> A) B) C) D) <div style=padding-top: 35px> <strong>Identify the pair of graphs that correspond most closely to the solutions of with , respectively. [The function y(t) is plotted on the vertical axes and t is plotted on the horizontal axes.]</strong> A) B) C) D) <div style=padding-top: 35px>
Question
Find the recurrence relation for the general power series solution <strong>Find the recurrence relation for the general power series solution to the second order equation .</strong> A) B) C) D) <div style=padding-top: 35px> to the second order equation <strong>Find the recurrence relation for the general power series solution to the second order equation .</strong> A) B) C) D) <div style=padding-top: 35px> .

A) <strong>Find the recurrence relation for the general power series solution to the second order equation .</strong> A) B) C) D) <div style=padding-top: 35px>
B) <strong>Find the recurrence relation for the general power series solution to the second order equation .</strong> A) B) C) D) <div style=padding-top: 35px>
C) <strong>Find the recurrence relation for the general power series solution to the second order equation .</strong> A) B) C) D) <div style=padding-top: 35px>
D) <strong>Find the recurrence relation for the general power series solution to the second order equation .</strong> A) B) C) D) <div style=padding-top: 35px>
Question
A pendulum has length 0.20 meter. A bob is released from rest from a starting angle <strong>A pendulum has length 0.20 meter. A bob is released from rest from a starting angle . Find an equation for the position at any time t and find the amplitude and period of the motion. [The acceleration due to gravity is 9.8 m s<sup>-2</sup>.]</strong> A) amplitude: 0.15 m; period: 0.898 rad B) amplitude: 0.15 m; period: 0.449 rad C) amplitude: 0.3 m; period: 0.449 rad D) amplitude: 0.3 m; period: 0.898 rad <div style=padding-top: 35px> . Find an equation for the position at any time t and find the amplitude and period of the motion. [The acceleration due to gravity is 9.8 m s-2.]

A) amplitude: 0.15 m; period: 0.898 rad
B) amplitude: 0.15 m; period: 0.449 rad
C) amplitude: 0.3 m; period: 0.449 rad
D) amplitude: 0.3 m; period: 0.898 rad
Question
A series circuit has an 0.1 henry inductor, a 300 ohm resistor, and a 10-4 farad capacitor. The initial charge on the capacitor is 10-6 coulombs, and there is no initial current nor applied voltage. Identify the function that describes the charge on the capacitor as a function of time.

A) <strong>A series circuit has an 0.1 henry inductor, a 300 ohm resistor, and a 10<sup>-4</sup> farad capacitor. The initial charge on the capacitor is 10<sup>-</sup><sup>6 </sup>coulombs, and there is no initial current nor applied voltage. Identify the function that describes the charge on the capacitor as a function of time.</strong> A) B) C) D) <div style=padding-top: 35px>
B) <strong>A series circuit has an 0.1 henry inductor, a 300 ohm resistor, and a 10<sup>-4</sup> farad capacitor. The initial charge on the capacitor is 10<sup>-</sup><sup>6 </sup>coulombs, and there is no initial current nor applied voltage. Identify the function that describes the charge on the capacitor as a function of time.</strong> A) B) C) D) <div style=padding-top: 35px>
C) <strong>A series circuit has an 0.1 henry inductor, a 300 ohm resistor, and a 10<sup>-4</sup> farad capacitor. The initial charge on the capacitor is 10<sup>-</sup><sup>6 </sup>coulombs, and there is no initial current nor applied voltage. Identify the function that describes the charge on the capacitor as a function of time.</strong> A) B) C) D) <div style=padding-top: 35px>
D) <strong>A series circuit has an 0.1 henry inductor, a 300 ohm resistor, and a 10<sup>-4</sup> farad capacitor. The initial charge on the capacitor is 10<sup>-</sup><sup>6 </sup>coulombs, and there is no initial current nor applied voltage. Identify the function that describes the charge on the capacitor as a function of time.</strong> A) B) C) D) <div style=padding-top: 35px>
Question
A second order differential equation can be arranged to the form <strong>A second order differential equation can be arranged to the form , and one can find the third and higher derivatives of y by simply differentiating this equation. Since a Taylor-series expansion of a function y(x) is , one can differentiate the rearranged second order differential equation to evaluate coefficients in the Taylor polynomial, if one is either given or can solve for the initial condition y(0) and y'(0). What is the coefficient of x<sup>4</sup> in the Taylor polynomial expansion of the solution to the equation if the initial conditions are ?</strong> A) B) C) D) <div style=padding-top: 35px> , and one can find the third and higher derivatives of y by simply differentiating this equation. Since a Taylor-series expansion of a function y(x) is <strong>A second order differential equation can be arranged to the form , and one can find the third and higher derivatives of y by simply differentiating this equation. Since a Taylor-series expansion of a function y(x) is , one can differentiate the rearranged second order differential equation to evaluate coefficients in the Taylor polynomial, if one is either given or can solve for the initial condition y(0) and y'(0). What is the coefficient of x<sup>4</sup> in the Taylor polynomial expansion of the solution to the equation if the initial conditions are ?</strong> A) B) C) D) <div style=padding-top: 35px> , one can differentiate the rearranged second order differential equation to evaluate coefficients in the Taylor polynomial, if one is either given or can solve for the initial condition y(0) and y'(0). What is the coefficient of x4 in the Taylor polynomial expansion of the solution to the equation <strong>A second order differential equation can be arranged to the form , and one can find the third and higher derivatives of y by simply differentiating this equation. Since a Taylor-series expansion of a function y(x) is , one can differentiate the rearranged second order differential equation to evaluate coefficients in the Taylor polynomial, if one is either given or can solve for the initial condition y(0) and y'(0). What is the coefficient of x<sup>4</sup> in the Taylor polynomial expansion of the solution to the equation if the initial conditions are ?</strong> A) B) C) D) <div style=padding-top: 35px> if the initial conditions are <strong>A second order differential equation can be arranged to the form , and one can find the third and higher derivatives of y by simply differentiating this equation. Since a Taylor-series expansion of a function y(x) is , one can differentiate the rearranged second order differential equation to evaluate coefficients in the Taylor polynomial, if one is either given or can solve for the initial condition y(0) and y'(0). What is the coefficient of x<sup>4</sup> in the Taylor polynomial expansion of the solution to the equation if the initial conditions are ?</strong> A) B) C) D) <div style=padding-top: 35px> ?

A) <strong>A second order differential equation can be arranged to the form , and one can find the third and higher derivatives of y by simply differentiating this equation. Since a Taylor-series expansion of a function y(x) is , one can differentiate the rearranged second order differential equation to evaluate coefficients in the Taylor polynomial, if one is either given or can solve for the initial condition y(0) and y'(0). What is the coefficient of x<sup>4</sup> in the Taylor polynomial expansion of the solution to the equation if the initial conditions are ?</strong> A) B) C) D) <div style=padding-top: 35px>
B) <strong>A second order differential equation can be arranged to the form , and one can find the third and higher derivatives of y by simply differentiating this equation. Since a Taylor-series expansion of a function y(x) is , one can differentiate the rearranged second order differential equation to evaluate coefficients in the Taylor polynomial, if one is either given or can solve for the initial condition y(0) and y'(0). What is the coefficient of x<sup>4</sup> in the Taylor polynomial expansion of the solution to the equation if the initial conditions are ?</strong> A) B) C) D) <div style=padding-top: 35px>
C) <strong>A second order differential equation can be arranged to the form , and one can find the third and higher derivatives of y by simply differentiating this equation. Since a Taylor-series expansion of a function y(x) is , one can differentiate the rearranged second order differential equation to evaluate coefficients in the Taylor polynomial, if one is either given or can solve for the initial condition y(0) and y'(0). What is the coefficient of x<sup>4</sup> in the Taylor polynomial expansion of the solution to the equation if the initial conditions are ?</strong> A) B) C) D) <div style=padding-top: 35px>
D) <strong>A second order differential equation can be arranged to the form , and one can find the third and higher derivatives of y by simply differentiating this equation. Since a Taylor-series expansion of a function y(x) is , one can differentiate the rearranged second order differential equation to evaluate coefficients in the Taylor polynomial, if one is either given or can solve for the initial condition y(0) and y'(0). What is the coefficient of x<sup>4</sup> in the Taylor polynomial expansion of the solution to the equation if the initial conditions are ?</strong> A) B) C) D) <div style=padding-top: 35px>
Question
A series circuit has a 0.1 henry inductor, a 320 ohm resistor, and a 0.000006 farad capacitor. There is an initial charge of 0.000003 coulombs, there is no initial current, and there is an applied voltage which is described as <strong>A series circuit has a 0.1 henry inductor, a 320 ohm resistor, and a 0.000006 farad capacitor. There is an initial charge of 0.000003 coulombs, there is no initial current, and there is an applied voltage which is described as . Identify the steady-state solution to the differential equation.</strong> A) B) C) D) <div style=padding-top: 35px> . Identify the steady-state solution to the differential equation.

A) <strong>A series circuit has a 0.1 henry inductor, a 320 ohm resistor, and a 0.000006 farad capacitor. There is an initial charge of 0.000003 coulombs, there is no initial current, and there is an applied voltage which is described as . Identify the steady-state solution to the differential equation.</strong> A) B) C) D) <div style=padding-top: 35px>
B) <strong>A series circuit has a 0.1 henry inductor, a 320 ohm resistor, and a 0.000006 farad capacitor. There is an initial charge of 0.000003 coulombs, there is no initial current, and there is an applied voltage which is described as . Identify the steady-state solution to the differential equation.</strong> A) B) C) D) <div style=padding-top: 35px>
C) <strong>A series circuit has a 0.1 henry inductor, a 320 ohm resistor, and a 0.000006 farad capacitor. There is an initial charge of 0.000003 coulombs, there is no initial current, and there is an applied voltage which is described as . Identify the steady-state solution to the differential equation.</strong> A) B) C) D) <div style=padding-top: 35px>
D) <strong>A series circuit has a 0.1 henry inductor, a 320 ohm resistor, and a 0.000006 farad capacitor. There is an initial charge of 0.000003 coulombs, there is no initial current, and there is an applied voltage which is described as . Identify the steady-state solution to the differential equation.</strong> A) B) C) D) <div style=padding-top: 35px>
Question
Solve the initial value problem <strong>Solve the initial value problem , .</strong> A) B) C) D) <div style=padding-top: 35px> , <strong>Solve the initial value problem , .</strong> A) B) C) D) <div style=padding-top: 35px> .

A) <strong>Solve the initial value problem , .</strong> A) B) C) D) <div style=padding-top: 35px>
B) <strong>Solve the initial value problem , .</strong> A) B) C) D) <div style=padding-top: 35px>
C) <strong>Solve the initial value problem , .</strong> A) B) C) D) <div style=padding-top: 35px>
D) <strong>Solve the initial value problem , .</strong> A) B) C) D) <div style=padding-top: 35px>
Question
A series circuit has a 0.15 henry inductor, a 360 ohm resistor, and a 0.00001 farad capacitor. There is an initial charge of 0.000006 coulombs, there is no initial current, and there is an applied voltage which is described as <strong>A series circuit has a 0.15 henry inductor, a 360 ohm resistor, and a 0.00001 farad capacitor. There is an initial charge of 0.000006 coulombs, there is no initial current, and there is an applied voltage which is described as . Identify the amplitude of the steady-state solution.</strong> A) 0.000003 B) 0.000009 C) 0.35 D) 0.175 <div style=padding-top: 35px> . Identify the amplitude of the steady-state solution.

A) 0.000003
B) 0.000009
C) 0.35
D) 0.175
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Deck 16: Second Order Differential Equations
1
Identify the general solution of the the differential equation <strong>Identify the general solution of the the differential equation .</strong> A) B) C) D) .

A) <strong>Identify the general solution of the the differential equation .</strong> A) B) C) D)
B) <strong>Identify the general solution of the the differential equation .</strong> A) B) C) D)
C) <strong>Identify the general solution of the the differential equation .</strong> A) B) C) D)
D) <strong>Identify the general solution of the the differential equation .</strong> A) B) C) D)
C
2
Solve the initial value problem <strong>Solve the initial value problem , .</strong> A) B) C) D) , <strong>Solve the initial value problem , .</strong> A) B) C) D) .

A) <strong>Solve the initial value problem , .</strong> A) B) C) D)
B) <strong>Solve the initial value problem , .</strong> A) B) C) D)
C) <strong>Solve the initial value problem , .</strong> A) B) C) D)
D) <strong>Solve the initial value problem , .</strong> A) B) C) D)
A
3
Identify the general solution of the the differential equation <strong>Identify the general solution of the the differential equation .</strong> A) B) C) D) .

A) <strong>Identify the general solution of the the differential equation .</strong> A) B) C) D)
B) <strong>Identify the general solution of the the differential equation .</strong> A) B) C) D)
C) <strong>Identify the general solution of the the differential equation .</strong> A) B) C) D)
D) <strong>Identify the general solution of the the differential equation .</strong> A) B) C) D)
A
4
Solve the initial value problem. Solve the initial value problem.
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5
A 0.15 kg mass hangs on a spring with a 2 N m-1 force constant and its motion is damped proportional to its velocity with proportionality constant 0.2 kg s-1. If the system is subjected to an external variable-frequency vibration described as <strong>A 0.15 kg mass hangs on a spring with a 2 N m<sup>-1</sup> force constant and its motion is damped proportional to its velocity with proportionality constant 0.2 kg s<sup>-1</sup>. If the system is subjected to an external variable-frequency vibration described as newtons, what will be the amplitude of the steady-state oscillation?</strong> A) 2.03 m B) 4.14 m C) 0.12 m D) 0.00 m newtons, what will be the amplitude of the steady-state oscillation?

A) 2.03 m
B) 4.14 m
C) 0.12 m
D) 0.00 m
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6
Consider solutions to the second order differential equation <strong>Consider solutions to the second order differential equation in which m, c, and k are positive constants. Which of the following pairs of graphs might correspond to the sets of constants m = 1.00, c = 0.80, and k = 1.20 (blue graph), and m = 1.00, c = 0.08, and k = 1.20 (red graph) ?</strong> A) B) C) D) in which m, c, and k are positive constants. Which of the following pairs of graphs might correspond to the sets of constants m = 1.00, c = 0.80, and k = 1.20 (blue graph), and m = 1.00, c = 0.08, and k = 1.20 (red graph) ?

A) <strong>Consider solutions to the second order differential equation in which m, c, and k are positive constants. Which of the following pairs of graphs might correspond to the sets of constants m = 1.00, c = 0.80, and k = 1.20 (blue graph), and m = 1.00, c = 0.08, and k = 1.20 (red graph) ?</strong> A) B) C) D) <strong>Consider solutions to the second order differential equation in which m, c, and k are positive constants. Which of the following pairs of graphs might correspond to the sets of constants m = 1.00, c = 0.80, and k = 1.20 (blue graph), and m = 1.00, c = 0.08, and k = 1.20 (red graph) ?</strong> A) B) C) D)
B) <strong>Consider solutions to the second order differential equation in which m, c, and k are positive constants. Which of the following pairs of graphs might correspond to the sets of constants m = 1.00, c = 0.80, and k = 1.20 (blue graph), and m = 1.00, c = 0.08, and k = 1.20 (red graph) ?</strong> A) B) C) D) <strong>Consider solutions to the second order differential equation in which m, c, and k are positive constants. Which of the following pairs of graphs might correspond to the sets of constants m = 1.00, c = 0.80, and k = 1.20 (blue graph), and m = 1.00, c = 0.08, and k = 1.20 (red graph) ?</strong> A) B) C) D)
C) <strong>Consider solutions to the second order differential equation in which m, c, and k are positive constants. Which of the following pairs of graphs might correspond to the sets of constants m = 1.00, c = 0.80, and k = 1.20 (blue graph), and m = 1.00, c = 0.08, and k = 1.20 (red graph) ?</strong> A) B) C) D) <strong>Consider solutions to the second order differential equation in which m, c, and k are positive constants. Which of the following pairs of graphs might correspond to the sets of constants m = 1.00, c = 0.80, and k = 1.20 (blue graph), and m = 1.00, c = 0.08, and k = 1.20 (red graph) ?</strong> A) B) C) D)
D) <strong>Consider solutions to the second order differential equation in which m, c, and k are positive constants. Which of the following pairs of graphs might correspond to the sets of constants m = 1.00, c = 0.80, and k = 1.20 (blue graph), and m = 1.00, c = 0.08, and k = 1.20 (red graph) ?</strong> A) B) C) D) <strong>Consider solutions to the second order differential equation in which m, c, and k are positive constants. Which of the following pairs of graphs might correspond to the sets of constants m = 1.00, c = 0.80, and k = 1.20 (blue graph), and m = 1.00, c = 0.08, and k = 1.20 (red graph) ?</strong> A) B) C) D)
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7
A spring is stretched 5 cm by a 1-kg mass. The mass is set in motion from its equilibrium position with an upward velocity of 2 m/s. The damping constant equals A spring is stretched 5 cm by a 1-kg mass. The mass is set in motion from its equilibrium position with an upward velocity of 2 m/s. The damping constant equals Find an equation for the position of the mass at any time t. Find an equation for the position of the mass at any time t.
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8
Determine the form of a particular solution of the equation. <strong>Determine the form of a particular solution of the equation. </strong> A) B) C) D)

A) <strong>Determine the form of a particular solution of the equation. </strong> A) B) C) D)
B) <strong>Determine the form of a particular solution of the equation. </strong> A) B) C) D)
C) <strong>Determine the form of a particular solution of the equation. </strong> A) B) C) D)
D) <strong>Determine the form of a particular solution of the equation. </strong> A) B) C) D)
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9
Identify the form of a particular solution to the equation <strong>Identify the form of a particular solution to the equation .</strong> A) B) C) D) .

A) <strong>Identify the form of a particular solution to the equation .</strong> A) B) C) D)
B) <strong>Identify the form of a particular solution to the equation .</strong> A) B) C) D)
C) <strong>Identify the form of a particular solution to the equation .</strong> A) B) C) D)
D) <strong>Identify the form of a particular solution to the equation .</strong> A) B) C) D)
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10
Find the general solution of <strong>Find the general solution of , given the particular solution .</strong> A) B) C) D) , given the particular solution <strong>Find the general solution of , given the particular solution .</strong> A) B) C) D) .

A) <strong>Find the general solution of , given the particular solution .</strong> A) B) C) D)
B) <strong>Find the general solution of , given the particular solution .</strong> A) B) C) D)
C) <strong>Find the general solution of , given the particular solution .</strong> A) B) C) D)
D) <strong>Find the general solution of , given the particular solution .</strong> A) B) C) D)
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11
Solve the initial value problem <strong>Solve the initial value problem , .</strong> A) B) C) D) , <strong>Solve the initial value problem , .</strong> A) B) C) D) .

A) <strong>Solve the initial value problem , .</strong> A) B) C) D)
B) <strong>Solve the initial value problem , .</strong> A) B) C) D)
C) <strong>Solve the initial value problem , .</strong> A) B) C) D)
D) <strong>Solve the initial value problem , .</strong> A) B) C) D)
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12
A certain spring is at rest when stretched 0.392 m by a 2.0 kg mass. Which function describes the motion of the mass if it is pulled down 0.25 m and released without imparting any initial velocity at time t = 0? Other helpful information: the motion is not damped; use 9.8 m s-2 as the acceleration due to gravity; and consider the zero position to be the rest position of the spring with the mass attached, and downward motion defines the positive x direction.

A) <strong>A certain spring is at rest when stretched 0.392 m by a 2.0 kg mass. Which function describes the motion of the mass if it is pulled down 0.25 m and released without imparting any initial velocity at time t = 0? Other helpful information: the motion is not damped; use 9.8 m s<sup>-2</sup> as the acceleration due to gravity; and consider the zero position to be the rest position of the spring with the mass attached, and downward motion defines the positive x direction.</strong> A) B) C) D)
B) <strong>A certain spring is at rest when stretched 0.392 m by a 2.0 kg mass. Which function describes the motion of the mass if it is pulled down 0.25 m and released without imparting any initial velocity at time t = 0? Other helpful information: the motion is not damped; use 9.8 m s<sup>-2</sup> as the acceleration due to gravity; and consider the zero position to be the rest position of the spring with the mass attached, and downward motion defines the positive x direction.</strong> A) B) C) D)
C) <strong>A certain spring is at rest when stretched 0.392 m by a 2.0 kg mass. Which function describes the motion of the mass if it is pulled down 0.25 m and released without imparting any initial velocity at time t = 0? Other helpful information: the motion is not damped; use 9.8 m s<sup>-2</sup> as the acceleration due to gravity; and consider the zero position to be the rest position of the spring with the mass attached, and downward motion defines the positive x direction.</strong> A) B) C) D)
D) <strong>A certain spring is at rest when stretched 0.392 m by a 2.0 kg mass. Which function describes the motion of the mass if it is pulled down 0.25 m and released without imparting any initial velocity at time t = 0? Other helpful information: the motion is not damped; use 9.8 m s<sup>-2</sup> as the acceleration due to gravity; and consider the zero position to be the rest position of the spring with the mass attached, and downward motion defines the positive x direction.</strong> A) B) C) D)
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13
Identify the form of a particular solution to the equation <strong>Identify the form of a particular solution to the equation .</strong> A) B) C) D) .

A) <strong>Identify the form of a particular solution to the equation .</strong> A) B) C) D)
B) <strong>Identify the form of a particular solution to the equation .</strong> A) B) C) D)
C) <strong>Identify the form of a particular solution to the equation .</strong> A) B) C) D)
D) <strong>Identify the form of a particular solution to the equation .</strong> A) B) C) D)
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14
Find the general solution of <strong>Find the general solution of , given the particular solution .</strong> A) B) C) D) , given the particular solution <strong>Find the general solution of , given the particular solution .</strong> A) B) C) D) .

A) <strong>Find the general solution of , given the particular solution .</strong> A) B) C) D)
B) <strong>Find the general solution of , given the particular solution .</strong> A) B) C) D)
C) <strong>Find the general solution of , given the particular solution .</strong> A) B) C) D)
D) <strong>Find the general solution of , given the particular solution .</strong> A) B) C) D)
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15
A 2.0 kg mass hangs on a spring with a 1.1 newton/meter force constant and its motion is not damped. If the system is subjected to an external variable-frequency vibration described as <strong>A 2.0 kg mass hangs on a spring with a 1.1 newton/meter force constant and its motion is not damped. If the system is subjected to an external variable-frequency vibration described as newtons, at what frequency, , will the external vibration and the spring system be in resonance?</strong> A) 0.55 s<sup>-1</sup> B) 0.74 s<sup>-1</sup> C) 1.82 s<sup>-1</sup> D) 1.35 s<sup>-1</sup> newtons, at what frequency, <strong>A 2.0 kg mass hangs on a spring with a 1.1 newton/meter force constant and its motion is not damped. If the system is subjected to an external variable-frequency vibration described as newtons, at what frequency, , will the external vibration and the spring system be in resonance?</strong> A) 0.55 s<sup>-1</sup> B) 0.74 s<sup>-1</sup> C) 1.82 s<sup>-1</sup> D) 1.35 s<sup>-1</sup> , will the external vibration and the spring system be in resonance?

A) 0.55 s-1
B) 0.74 s-1
C) 1.82 s-1
D) 1.35 s-1
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16
Solve the initial value problem <strong>Solve the initial value problem , .</strong> A) B) C) D) , <strong>Solve the initial value problem , .</strong> A) B) C) D) .

A) <strong>Solve the initial value problem , .</strong> A) B) C) D)
B) <strong>Solve the initial value problem , .</strong> A) B) C) D)
C) <strong>Solve the initial value problem , .</strong> A) B) C) D)
D) <strong>Solve the initial value problem , .</strong> A) B) C) D)
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17
Find the general solution of the equation <strong>Find the general solution of the equation .</strong> A) B) C) D) .

A) <strong>Find the general solution of the equation .</strong> A) B) C) D)
B) <strong>Find the general solution of the equation .</strong> A) B) C) D)
C) <strong>Find the general solution of the equation .</strong> A) B) C) D)
D) <strong>Find the general solution of the equation .</strong> A) B) C) D)
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18
Find the general solution of the differential equation. <strong>Find the general solution of the differential equation. </strong> A) B) C) D)

A) <strong>Find the general solution of the differential equation. </strong> A) B) C) D)
B) <strong>Find the general solution of the differential equation. </strong> A) B) C) D)
C) <strong>Find the general solution of the differential equation. </strong> A) B) C) D)
D) <strong>Find the general solution of the differential equation. </strong> A) B) C) D)
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19
Identify the general solution of the the differential equation <strong>Identify the general solution of the the differential equation .</strong> A) B) C) D) .

A) <strong>Identify the general solution of the the differential equation .</strong> A) B) C) D)
B) <strong>Identify the general solution of the the differential equation .</strong> A) B) C) D)
C) <strong>Identify the general solution of the the differential equation .</strong> A) B) C) D)
D) <strong>Identify the general solution of the the differential equation .</strong> A) B) C) D)
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20
For For find the steady-state solution and identify its amplitude and phase shift. find the steady-state solution and identify its amplitude and phase shift.
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21
A series circuit has a 0.15 henry inductor, a 350 ohm resistor, and a 0.00001 farad capacitor. There is an initial charge of 0.000001 coulombs, there is no initial current, and there is an applied voltage which is described as <strong>A series circuit has a 0.15 henry inductor, a 350 ohm resistor, and a 0.00001 farad capacitor. There is an initial charge of 0.000001 coulombs, there is no initial current, and there is an applied voltage which is described as . Identify the solution to the differential equation that describes the charge on the capacitor as a function of time.</strong> A) B) C) D) . Identify the solution to the differential equation that describes the charge on the capacitor as a function of time.

A) <strong>A series circuit has a 0.15 henry inductor, a 350 ohm resistor, and a 0.00001 farad capacitor. There is an initial charge of 0.000001 coulombs, there is no initial current, and there is an applied voltage which is described as . Identify the solution to the differential equation that describes the charge on the capacitor as a function of time.</strong> A) B) C) D)
B) <strong>A series circuit has a 0.15 henry inductor, a 350 ohm resistor, and a 0.00001 farad capacitor. There is an initial charge of 0.000001 coulombs, there is no initial current, and there is an applied voltage which is described as . Identify the solution to the differential equation that describes the charge on the capacitor as a function of time.</strong> A) B) C) D)
C) <strong>A series circuit has a 0.15 henry inductor, a 350 ohm resistor, and a 0.00001 farad capacitor. There is an initial charge of 0.000001 coulombs, there is no initial current, and there is an applied voltage which is described as . Identify the solution to the differential equation that describes the charge on the capacitor as a function of time.</strong> A) B) C) D)
D) <strong>A series circuit has a 0.15 henry inductor, a 350 ohm resistor, and a 0.00001 farad capacitor. There is an initial charge of 0.000001 coulombs, there is no initial current, and there is an applied voltage which is described as . Identify the solution to the differential equation that describes the charge on the capacitor as a function of time.</strong> A) B) C) D)
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22
A second order differential equaiton can be arranged to the form <strong>A second order differential equaiton can be arranged to the form , and one can find the third and higher derivatives of y by simply differentiating this equation. Since a Taylor series expansion of a function y(x) is , one can differentiate the rearranged second order differential equation to evaluate coefficients of the Taylor polynomial, if one is either given or can solve for the initial condition y(0) and y'(0). What does the fourth-degree Taylor polynomial look like for the solution to the equation if the initial conditions are ?</strong> A) B) C) D) , and one can find the third and higher derivatives of y by simply differentiating this equation. Since a Taylor series expansion of a function y(x) is <strong>A second order differential equaiton can be arranged to the form , and one can find the third and higher derivatives of y by simply differentiating this equation. Since a Taylor series expansion of a function y(x) is , one can differentiate the rearranged second order differential equation to evaluate coefficients of the Taylor polynomial, if one is either given or can solve for the initial condition y(0) and y'(0). What does the fourth-degree Taylor polynomial look like for the solution to the equation if the initial conditions are ?</strong> A) B) C) D) , one can differentiate the rearranged second order differential equation to evaluate coefficients of the Taylor polynomial, if one is either given or can solve for the initial condition y(0) and y'(0). What does the fourth-degree Taylor polynomial look like for the solution to the equation <strong>A second order differential equaiton can be arranged to the form , and one can find the third and higher derivatives of y by simply differentiating this equation. Since a Taylor series expansion of a function y(x) is , one can differentiate the rearranged second order differential equation to evaluate coefficients of the Taylor polynomial, if one is either given or can solve for the initial condition y(0) and y'(0). What does the fourth-degree Taylor polynomial look like for the solution to the equation if the initial conditions are ?</strong> A) B) C) D) if the initial conditions are <strong>A second order differential equaiton can be arranged to the form , and one can find the third and higher derivatives of y by simply differentiating this equation. Since a Taylor series expansion of a function y(x) is , one can differentiate the rearranged second order differential equation to evaluate coefficients of the Taylor polynomial, if one is either given or can solve for the initial condition y(0) and y'(0). What does the fourth-degree Taylor polynomial look like for the solution to the equation if the initial conditions are ?</strong> A) B) C) D) ?

A) <strong>A second order differential equaiton can be arranged to the form , and one can find the third and higher derivatives of y by simply differentiating this equation. Since a Taylor series expansion of a function y(x) is , one can differentiate the rearranged second order differential equation to evaluate coefficients of the Taylor polynomial, if one is either given or can solve for the initial condition y(0) and y'(0). What does the fourth-degree Taylor polynomial look like for the solution to the equation if the initial conditions are ?</strong> A) B) C) D)
B) <strong>A second order differential equaiton can be arranged to the form , and one can find the third and higher derivatives of y by simply differentiating this equation. Since a Taylor series expansion of a function y(x) is , one can differentiate the rearranged second order differential equation to evaluate coefficients of the Taylor polynomial, if one is either given or can solve for the initial condition y(0) and y'(0). What does the fourth-degree Taylor polynomial look like for the solution to the equation if the initial conditions are ?</strong> A) B) C) D)
C) <strong>A second order differential equaiton can be arranged to the form , and one can find the third and higher derivatives of y by simply differentiating this equation. Since a Taylor series expansion of a function y(x) is , one can differentiate the rearranged second order differential equation to evaluate coefficients of the Taylor polynomial, if one is either given or can solve for the initial condition y(0) and y'(0). What does the fourth-degree Taylor polynomial look like for the solution to the equation if the initial conditions are ?</strong> A) B) C) D)
D) <strong>A second order differential equaiton can be arranged to the form , and one can find the third and higher derivatives of y by simply differentiating this equation. Since a Taylor series expansion of a function y(x) is , one can differentiate the rearranged second order differential equation to evaluate coefficients of the Taylor polynomial, if one is either given or can solve for the initial condition y(0) and y'(0). What does the fourth-degree Taylor polynomial look like for the solution to the equation if the initial conditions are ?</strong> A) B) C) D)
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23
Find the recurrence relation for the general power series solution <strong>Find the recurrence relation for the general power series solution to the second order equation .</strong> A) B) C) D) to the second order equation <strong>Find the recurrence relation for the general power series solution to the second order equation .</strong> A) B) C) D) .

A) <strong>Find the recurrence relation for the general power series solution to the second order equation .</strong> A) B) C) D)
B) <strong>Find the recurrence relation for the general power series solution to the second order equation .</strong> A) B) C) D)
C) <strong>Find the recurrence relation for the general power series solution to the second order equation .</strong> A) B) C) D)
D) <strong>Find the recurrence relation for the general power series solution to the second order equation .</strong> A) B) C) D)
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24
Suppose that the charge in a circuit satisfies the equation <strong>Suppose that the charge in a circuit satisfies the equation Find the gain of the circuit.</strong> A) B) C) D) Find the gain of the circuit.

A) <strong>Suppose that the charge in a circuit satisfies the equation Find the gain of the circuit.</strong> A) B) C) D)
B) <strong>Suppose that the charge in a circuit satisfies the equation Find the gain of the circuit.</strong> A) B) C) D)
C) <strong>Suppose that the charge in a circuit satisfies the equation Find the gain of the circuit.</strong> A) B) C) D)
D) <strong>Suppose that the charge in a circuit satisfies the equation Find the gain of the circuit.</strong> A) B) C) D)
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25
Identify the radius of convergence of the power series solutions about x = 0 of <strong>Identify the radius of convergence of the power series solutions about x = 0 of .</strong> A) B) C) D) .

A) <strong>Identify the radius of convergence of the power series solutions about x = 0 of .</strong> A) B) C) D)
B) <strong>Identify the radius of convergence of the power series solutions about x = 0 of .</strong> A) B) C) D)
C) <strong>Identify the radius of convergence of the power series solutions about x = 0 of .</strong> A) B) C) D)
D) <strong>Identify the radius of convergence of the power series solutions about x = 0 of .</strong> A) B) C) D)
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26
Identify the radius of convergence of the power series solutions about x = 0 of <strong>Identify the radius of convergence of the power series solutions about x = 0 of .</strong> A) R = 0 B) C) R = D) R = 4 .

A) R = 0
B) <strong>Identify the radius of convergence of the power series solutions about x = 0 of .</strong> A) R = 0 B) C) R = D) R = 4
C) R = <strong>Identify the radius of convergence of the power series solutions about x = 0 of .</strong> A) R = 0 B) C) R = D) R = 4
D) R = 4
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27
Solve the initial value problem <strong>Solve the initial value problem , .</strong> A) B) C) D) , <strong>Solve the initial value problem , .</strong> A) B) C) D) .

A) <strong>Solve the initial value problem , .</strong> A) B) C) D)
B) <strong>Solve the initial value problem , .</strong> A) B) C) D)
C) <strong>Solve the initial value problem , .</strong> A) B) C) D)
D) <strong>Solve the initial value problem , .</strong> A) B) C) D)
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28
For a pendulum of weight 4 pounds, length 0.75 ft, damping constant <strong>For a pendulum of weight 4 pounds, length 0.75 ft, damping constant and forcing function find the amplitude and period of the steady-state motion. [The acceleration due to gravity is 32 ft s<sup>-2</sup>.]</strong> A) amplitude: 0.500 ft; period: 1.738 rad B) amplitude: 0.250 ft; period: 0.869 rad C) amplitude: 0.299 ft; period: 0.524 rad D) amplitude: 0.598 ft; period: 1.047 rad and forcing function <strong>For a pendulum of weight 4 pounds, length 0.75 ft, damping constant and forcing function find the amplitude and period of the steady-state motion. [The acceleration due to gravity is 32 ft s<sup>-2</sup>.]</strong> A) amplitude: 0.500 ft; period: 1.738 rad B) amplitude: 0.250 ft; period: 0.869 rad C) amplitude: 0.299 ft; period: 0.524 rad D) amplitude: 0.598 ft; period: 1.047 rad find the amplitude and period of the steady-state motion. [The acceleration due to gravity is 32 ft s-2.]

A) amplitude: 0.500 ft; period: 1.738 rad
B) amplitude: 0.250 ft; period: 0.869 rad
C) amplitude: 0.299 ft; period: 0.524 rad
D) amplitude: 0.598 ft; period: 1.047 rad
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29
A series circuit has a 0.2 henry inductor, a 490 ohm resistor, and a 0.000004 farad capacitor. There is an applied voltage which is described as <strong>A series circuit has a 0.2 henry inductor, a 490 ohm resistor, and a 0.000004 farad capacitor. There is an applied voltage which is described as . Identify the general solution to the differential equation that describes the charge on the capacitor as a function of time.</strong> A) B) C) D) . Identify the general solution to the differential equation that describes the charge on the capacitor as a function of time.

A) <strong>A series circuit has a 0.2 henry inductor, a 490 ohm resistor, and a 0.000004 farad capacitor. There is an applied voltage which is described as . Identify the general solution to the differential equation that describes the charge on the capacitor as a function of time.</strong> A) B) C) D)
B) <strong>A series circuit has a 0.2 henry inductor, a 490 ohm resistor, and a 0.000004 farad capacitor. There is an applied voltage which is described as . Identify the general solution to the differential equation that describes the charge on the capacitor as a function of time.</strong> A) B) C) D)
C) <strong>A series circuit has a 0.2 henry inductor, a 490 ohm resistor, and a 0.000004 farad capacitor. There is an applied voltage which is described as . Identify the general solution to the differential equation that describes the charge on the capacitor as a function of time.</strong> A) B) C) D)
D) <strong>A series circuit has a 0.2 henry inductor, a 490 ohm resistor, and a 0.000004 farad capacitor. There is an applied voltage which is described as . Identify the general solution to the differential equation that describes the charge on the capacitor as a function of time.</strong> A) B) C) D)
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30
A series circuit has a 0.1 henry inductor, a 330 ohm resistor, and a 0.000009 farad capacitor. There is an initial charge of 0.000002 coulombs, there is no initial current, and there is an applied voltage which is described as <strong>A series circuit has a 0.1 henry inductor, a 330 ohm resistor, and a 0.000009 farad capacitor. There is an initial charge of 0.000002 coulombs, there is no initial current, and there is an applied voltage which is described as . Identify the solution to the differential equation that describes the charge on the capacitor as a function of time.</strong> A) B) C) D) . Identify the solution to the differential equation that describes the charge on the capacitor as a function of time.

A) <strong>A series circuit has a 0.1 henry inductor, a 330 ohm resistor, and a 0.000009 farad capacitor. There is an initial charge of 0.000002 coulombs, there is no initial current, and there is an applied voltage which is described as . Identify the solution to the differential equation that describes the charge on the capacitor as a function of time.</strong> A) B) C) D)
B) <strong>A series circuit has a 0.1 henry inductor, a 330 ohm resistor, and a 0.000009 farad capacitor. There is an initial charge of 0.000002 coulombs, there is no initial current, and there is an applied voltage which is described as . Identify the solution to the differential equation that describes the charge on the capacitor as a function of time.</strong> A) B) C) D)
C) <strong>A series circuit has a 0.1 henry inductor, a 330 ohm resistor, and a 0.000009 farad capacitor. There is an initial charge of 0.000002 coulombs, there is no initial current, and there is an applied voltage which is described as . Identify the solution to the differential equation that describes the charge on the capacitor as a function of time.</strong> A) B) C) D)
D) <strong>A series circuit has a 0.1 henry inductor, a 330 ohm resistor, and a 0.000009 farad capacitor. There is an initial charge of 0.000002 coulombs, there is no initial current, and there is an applied voltage which is described as . Identify the solution to the differential equation that describes the charge on the capacitor as a function of time.</strong> A) B) C) D)
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31
Identify the pair of graphs that correspond most closely to the solutions of <strong>Identify the pair of graphs that correspond most closely to the solutions of with , respectively. [The function y(t) is plotted on the vertical axes and t is plotted on the horizontal axes.]</strong> A) B) C) D) with <strong>Identify the pair of graphs that correspond most closely to the solutions of with , respectively. [The function y(t) is plotted on the vertical axes and t is plotted on the horizontal axes.]</strong> A) B) C) D) , respectively. [The function y(t) is plotted on the vertical axes and t is plotted on the horizontal axes.]

A) <strong>Identify the pair of graphs that correspond most closely to the solutions of with , respectively. [The function y(t) is plotted on the vertical axes and t is plotted on the horizontal axes.]</strong> A) B) C) D) <strong>Identify the pair of graphs that correspond most closely to the solutions of with , respectively. [The function y(t) is plotted on the vertical axes and t is plotted on the horizontal axes.]</strong> A) B) C) D)
B) <strong>Identify the pair of graphs that correspond most closely to the solutions of with , respectively. [The function y(t) is plotted on the vertical axes and t is plotted on the horizontal axes.]</strong> A) B) C) D) <strong>Identify the pair of graphs that correspond most closely to the solutions of with , respectively. [The function y(t) is plotted on the vertical axes and t is plotted on the horizontal axes.]</strong> A) B) C) D)
C) <strong>Identify the pair of graphs that correspond most closely to the solutions of with , respectively. [The function y(t) is plotted on the vertical axes and t is plotted on the horizontal axes.]</strong> A) B) C) D) <strong>Identify the pair of graphs that correspond most closely to the solutions of with , respectively. [The function y(t) is plotted on the vertical axes and t is plotted on the horizontal axes.]</strong> A) B) C) D)
D) <strong>Identify the pair of graphs that correspond most closely to the solutions of with , respectively. [The function y(t) is plotted on the vertical axes and t is plotted on the horizontal axes.]</strong> A) B) C) D) <strong>Identify the pair of graphs that correspond most closely to the solutions of with , respectively. [The function y(t) is plotted on the vertical axes and t is plotted on the horizontal axes.]</strong> A) B) C) D)
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32
Find the recurrence relation for the general power series solution <strong>Find the recurrence relation for the general power series solution to the second order equation .</strong> A) B) C) D) to the second order equation <strong>Find the recurrence relation for the general power series solution to the second order equation .</strong> A) B) C) D) .

A) <strong>Find the recurrence relation for the general power series solution to the second order equation .</strong> A) B) C) D)
B) <strong>Find the recurrence relation for the general power series solution to the second order equation .</strong> A) B) C) D)
C) <strong>Find the recurrence relation for the general power series solution to the second order equation .</strong> A) B) C) D)
D) <strong>Find the recurrence relation for the general power series solution to the second order equation .</strong> A) B) C) D)
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33
A pendulum has length 0.20 meter. A bob is released from rest from a starting angle <strong>A pendulum has length 0.20 meter. A bob is released from rest from a starting angle . Find an equation for the position at any time t and find the amplitude and period of the motion. [The acceleration due to gravity is 9.8 m s<sup>-2</sup>.]</strong> A) amplitude: 0.15 m; period: 0.898 rad B) amplitude: 0.15 m; period: 0.449 rad C) amplitude: 0.3 m; period: 0.449 rad D) amplitude: 0.3 m; period: 0.898 rad . Find an equation for the position at any time t and find the amplitude and period of the motion. [The acceleration due to gravity is 9.8 m s-2.]

A) amplitude: 0.15 m; period: 0.898 rad
B) amplitude: 0.15 m; period: 0.449 rad
C) amplitude: 0.3 m; period: 0.449 rad
D) amplitude: 0.3 m; period: 0.898 rad
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34
A series circuit has an 0.1 henry inductor, a 300 ohm resistor, and a 10-4 farad capacitor. The initial charge on the capacitor is 10-6 coulombs, and there is no initial current nor applied voltage. Identify the function that describes the charge on the capacitor as a function of time.

A) <strong>A series circuit has an 0.1 henry inductor, a 300 ohm resistor, and a 10<sup>-4</sup> farad capacitor. The initial charge on the capacitor is 10<sup>-</sup><sup>6 </sup>coulombs, and there is no initial current nor applied voltage. Identify the function that describes the charge on the capacitor as a function of time.</strong> A) B) C) D)
B) <strong>A series circuit has an 0.1 henry inductor, a 300 ohm resistor, and a 10<sup>-4</sup> farad capacitor. The initial charge on the capacitor is 10<sup>-</sup><sup>6 </sup>coulombs, and there is no initial current nor applied voltage. Identify the function that describes the charge on the capacitor as a function of time.</strong> A) B) C) D)
C) <strong>A series circuit has an 0.1 henry inductor, a 300 ohm resistor, and a 10<sup>-4</sup> farad capacitor. The initial charge on the capacitor is 10<sup>-</sup><sup>6 </sup>coulombs, and there is no initial current nor applied voltage. Identify the function that describes the charge on the capacitor as a function of time.</strong> A) B) C) D)
D) <strong>A series circuit has an 0.1 henry inductor, a 300 ohm resistor, and a 10<sup>-4</sup> farad capacitor. The initial charge on the capacitor is 10<sup>-</sup><sup>6 </sup>coulombs, and there is no initial current nor applied voltage. Identify the function that describes the charge on the capacitor as a function of time.</strong> A) B) C) D)
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35
A second order differential equation can be arranged to the form <strong>A second order differential equation can be arranged to the form , and one can find the third and higher derivatives of y by simply differentiating this equation. Since a Taylor-series expansion of a function y(x) is , one can differentiate the rearranged second order differential equation to evaluate coefficients in the Taylor polynomial, if one is either given or can solve for the initial condition y(0) and y'(0). What is the coefficient of x<sup>4</sup> in the Taylor polynomial expansion of the solution to the equation if the initial conditions are ?</strong> A) B) C) D) , and one can find the third and higher derivatives of y by simply differentiating this equation. Since a Taylor-series expansion of a function y(x) is <strong>A second order differential equation can be arranged to the form , and one can find the third and higher derivatives of y by simply differentiating this equation. Since a Taylor-series expansion of a function y(x) is , one can differentiate the rearranged second order differential equation to evaluate coefficients in the Taylor polynomial, if one is either given or can solve for the initial condition y(0) and y'(0). What is the coefficient of x<sup>4</sup> in the Taylor polynomial expansion of the solution to the equation if the initial conditions are ?</strong> A) B) C) D) , one can differentiate the rearranged second order differential equation to evaluate coefficients in the Taylor polynomial, if one is either given or can solve for the initial condition y(0) and y'(0). What is the coefficient of x4 in the Taylor polynomial expansion of the solution to the equation <strong>A second order differential equation can be arranged to the form , and one can find the third and higher derivatives of y by simply differentiating this equation. Since a Taylor-series expansion of a function y(x) is , one can differentiate the rearranged second order differential equation to evaluate coefficients in the Taylor polynomial, if one is either given or can solve for the initial condition y(0) and y'(0). What is the coefficient of x<sup>4</sup> in the Taylor polynomial expansion of the solution to the equation if the initial conditions are ?</strong> A) B) C) D) if the initial conditions are <strong>A second order differential equation can be arranged to the form , and one can find the third and higher derivatives of y by simply differentiating this equation. Since a Taylor-series expansion of a function y(x) is , one can differentiate the rearranged second order differential equation to evaluate coefficients in the Taylor polynomial, if one is either given or can solve for the initial condition y(0) and y'(0). What is the coefficient of x<sup>4</sup> in the Taylor polynomial expansion of the solution to the equation if the initial conditions are ?</strong> A) B) C) D) ?

A) <strong>A second order differential equation can be arranged to the form , and one can find the third and higher derivatives of y by simply differentiating this equation. Since a Taylor-series expansion of a function y(x) is , one can differentiate the rearranged second order differential equation to evaluate coefficients in the Taylor polynomial, if one is either given or can solve for the initial condition y(0) and y'(0). What is the coefficient of x<sup>4</sup> in the Taylor polynomial expansion of the solution to the equation if the initial conditions are ?</strong> A) B) C) D)
B) <strong>A second order differential equation can be arranged to the form , and one can find the third and higher derivatives of y by simply differentiating this equation. Since a Taylor-series expansion of a function y(x) is , one can differentiate the rearranged second order differential equation to evaluate coefficients in the Taylor polynomial, if one is either given or can solve for the initial condition y(0) and y'(0). What is the coefficient of x<sup>4</sup> in the Taylor polynomial expansion of the solution to the equation if the initial conditions are ?</strong> A) B) C) D)
C) <strong>A second order differential equation can be arranged to the form , and one can find the third and higher derivatives of y by simply differentiating this equation. Since a Taylor-series expansion of a function y(x) is , one can differentiate the rearranged second order differential equation to evaluate coefficients in the Taylor polynomial, if one is either given or can solve for the initial condition y(0) and y'(0). What is the coefficient of x<sup>4</sup> in the Taylor polynomial expansion of the solution to the equation if the initial conditions are ?</strong> A) B) C) D)
D) <strong>A second order differential equation can be arranged to the form , and one can find the third and higher derivatives of y by simply differentiating this equation. Since a Taylor-series expansion of a function y(x) is , one can differentiate the rearranged second order differential equation to evaluate coefficients in the Taylor polynomial, if one is either given or can solve for the initial condition y(0) and y'(0). What is the coefficient of x<sup>4</sup> in the Taylor polynomial expansion of the solution to the equation if the initial conditions are ?</strong> A) B) C) D)
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36
A series circuit has a 0.1 henry inductor, a 320 ohm resistor, and a 0.000006 farad capacitor. There is an initial charge of 0.000003 coulombs, there is no initial current, and there is an applied voltage which is described as <strong>A series circuit has a 0.1 henry inductor, a 320 ohm resistor, and a 0.000006 farad capacitor. There is an initial charge of 0.000003 coulombs, there is no initial current, and there is an applied voltage which is described as . Identify the steady-state solution to the differential equation.</strong> A) B) C) D) . Identify the steady-state solution to the differential equation.

A) <strong>A series circuit has a 0.1 henry inductor, a 320 ohm resistor, and a 0.000006 farad capacitor. There is an initial charge of 0.000003 coulombs, there is no initial current, and there is an applied voltage which is described as . Identify the steady-state solution to the differential equation.</strong> A) B) C) D)
B) <strong>A series circuit has a 0.1 henry inductor, a 320 ohm resistor, and a 0.000006 farad capacitor. There is an initial charge of 0.000003 coulombs, there is no initial current, and there is an applied voltage which is described as . Identify the steady-state solution to the differential equation.</strong> A) B) C) D)
C) <strong>A series circuit has a 0.1 henry inductor, a 320 ohm resistor, and a 0.000006 farad capacitor. There is an initial charge of 0.000003 coulombs, there is no initial current, and there is an applied voltage which is described as . Identify the steady-state solution to the differential equation.</strong> A) B) C) D)
D) <strong>A series circuit has a 0.1 henry inductor, a 320 ohm resistor, and a 0.000006 farad capacitor. There is an initial charge of 0.000003 coulombs, there is no initial current, and there is an applied voltage which is described as . Identify the steady-state solution to the differential equation.</strong> A) B) C) D)
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37
Solve the initial value problem <strong>Solve the initial value problem , .</strong> A) B) C) D) , <strong>Solve the initial value problem , .</strong> A) B) C) D) .

A) <strong>Solve the initial value problem , .</strong> A) B) C) D)
B) <strong>Solve the initial value problem , .</strong> A) B) C) D)
C) <strong>Solve the initial value problem , .</strong> A) B) C) D)
D) <strong>Solve the initial value problem , .</strong> A) B) C) D)
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38
A series circuit has a 0.15 henry inductor, a 360 ohm resistor, and a 0.00001 farad capacitor. There is an initial charge of 0.000006 coulombs, there is no initial current, and there is an applied voltage which is described as <strong>A series circuit has a 0.15 henry inductor, a 360 ohm resistor, and a 0.00001 farad capacitor. There is an initial charge of 0.000006 coulombs, there is no initial current, and there is an applied voltage which is described as . Identify the amplitude of the steady-state solution.</strong> A) 0.000003 B) 0.000009 C) 0.35 D) 0.175 . Identify the amplitude of the steady-state solution.

A) 0.000003
B) 0.000009
C) 0.35
D) 0.175
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