What is the radius of convergence of the power series ? A) 5 B) 6 C) 36 D) $\infty$

The answer of What is the radius of convergence of...

What is the Taylor expansion for f(x) = cos(7x) about x = 0? A) B) C) D)

The answer of What is the Taylor expansion for f(x)...

What is the Taylor series expansion for f(x) = about x = 0? A) B) C) D) E)

The answer of What is the Taylor series expansion for...

Which of these power series is equivalent to + 7 ? A) B) C) ? D) ? E)

The answer of Which of these power series is equivalent...

Consider the first-order differential equation Assume a solution of this equation can be represented as a power series . Assume that C 0 is known. Which of these power series equals y(x)? A) $ \sum_{n=0}^{\infty} \frac{17 c_{0}}{3(n !)^{2}} x^{3 n} $ B) $ \sum_{n=0}^{\infty} \frac{c_{0} 17^{n}}{n ! 3} x^{3 n} $ C) $ \sum_{n=0}^{\infty} \frac{17 c_{0}}{3^{n} n !} x^{3 n} $ D) $ \sum_{n=0}^{\infty} \frac{17 c_{0}}{3^{n}(n !)^{2}} x^{3 n} $

The answer of Consider the first-order differential equation ...

Which of the following pairs forms a fundamental set of solutions of the Cauchy Euler differential equation . A) $ \left\{x^{-3}, x^{3}\right\} $ B) $ \left\{x^{3}, x^{6}\right\} $ C) $ \left\{x^{3}, x^{3} \ln x\right\} $ D) $ \left\{x^{-3}, x^{-3} \ln x\right\} $ E) $ \left\{x^{3} \cos (\ln x), x^{3} \sin (\ln x)\right\} $

The answer of Which of the following pairs forms a...

Which of the following pairs forms a fundamental set of solutions of the Cauchy Euler differential equation . A) $ \left\{x^{-5}, x^{-5} \cos (\ln x)\right\} $ B) $ \left\{x^{5}, x^{-5}\right\} $ C) $ \left\{x^{5}, x^{5} \ln x\right\} $ D) $ \left\{x^{-5}, x^{-5} \ln x\right\} $ E) $ \left\{x^{5}, x^{5} \cos (\ln x)\right\} $

The answer of Which of the following pairs forms a...

Which of the following pairs forms a fundamental set of solutions of the Cauchy Euler differential equation . A) $ \{\cos (6 \ln x), \sin (6 \ln x)\} $ B) $ \left\{x^{6} \cos (\ln x), x^{6} \sin (\ln x)\right\} $ C) $ \{\ln (\cos (6 x)), \ln (\sin (6 x))\} $ D) $ \left\{x^{-6}, x^{6}\right\} $ E) $ \{\cos (\ln (6 x)), \sin (\ln (6 x))\} $

The answer of Which of the following pairs forms a...

Find the general solution of the Cauchy Euler differential equation . A) $ y=C_{1} x^{-2}+C_{2} x^{-7} $ B) $ y=C_{1} x^{2}+C_{2} x^{-7} $ C) $ y=C_{1} x^{-2}+C_{2} x^{7} $ D) $ y=C_{1} x^{2}+C_{2} x^{7} $

The answer of Find the general solution of the Cauchy...

Find the general solution of the Cauchy Euler differential equation . A) $ y=C_{1}(x-3)^{5}+C_{2}(x-3)^{5} \ln x $ B) $ y=C_{1}(x-3)^{-5}+C_{2}(x-3)^{5} $ C)$ y=C_{1}(x-3)^{-5}+C_{2}(x-3)^{-5} \ln x $ D) $ y=C_{1}(x-3)^{5}+C_{2}(x-3)^{10} $

The answer of Find the general solution of the Cauchy...

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Deck 5: Series Solutions of Second-Order Linear Equations

سؤال

What is the radius of convergence of the power series $What is the radius of convergence of the power series ? A) 0 B) 1 C) 8 D) \infty <div style=padding-top: 35px>$ ?

A) 0
B) 1
C) 8
D)

\infty

استخدم زر المسافة أو

لقلب البطاقة.

سؤال

What is the radius of convergence of the power series $What is the radius of convergence of the power series ? A) B) 4 C) 2 D) 6 E) \infty <div style=padding-top: 35px>$ ?

A) $What is the radius of convergence of the power series ? A) B) 4 C) 2 D) 6 E) \infty <div style=padding-top: 35px>$
B) 4
C) 2
D) 6
E)

\infty

سؤال

What is the radius of convergence of the power series ?

A) 0
B)

C) 1
D) 6
E) 7

سؤال

What is the radius of convergence of the power series $What is the radius of convergence of the power series ? A) 5 B) 6 C) 36 D) \infty <div style=padding-top: 35px>$ ?

A) 5
B) 6
C) 36
D)

\infty

سؤال

What is the Taylor series expansion for f(x) = sin(6x) about x = 0?

سؤال

What is the Taylor expansion for f(x) = cos(7x) about x = 0?

سؤال

What is the Taylor series expansion for f(x) = about x = 0?

سؤال

Which of these power series is equivalent to ? Select all that apply.

سؤال

Which of these power series is equivalent to + 7 ?

C) ?

D) ?

سؤال

Which of these are singular points for the differential equation

Select all that apply.

A) -2
B) 6
C) -3
D) 2
E) 0

سؤال

Which of these are ordinary points for the differential equation
(x + 5) + ( - 49) + 2xy = 0?
Select all that apply.

A) -5
B) -7
C) 7
D) 0
E) 12

سؤال

Which of these are singular points for the differential equation

Select all that apply.

A) -5
B) -7
C) 5
D) 6
E) 7
F) 8

سؤال

Consider the second-order differential equation $Consider the second-order differential equation + 64y = 0. Assume a solution of this equation can be represented as a power series What is the recurrence relation for the coefficientsCn ? Assume that C0 and C1 are known. A) c_{n+2}+64 c_{n}=0, n=0,1,2, \ldots B) c_{n+1}+64 c_{n}=0, n=0,1,2, \ldots C) (n+1)(n+2) c_{n+2}+64 c_{n}=0, n=0,1,2, \ldots D) n(n+1) c_{n+1}+64 c_{n}=0, n=0,1,2, \ldots <div style=padding-top: 35px>$ + 64y = 0.
Assume a solution of this equation can be represented as a power series $Consider the second-order differential equation + 64y = 0. Assume a solution of this equation can be represented as a power series What is the recurrence relation for the coefficientsCn ? Assume that C0 and C1 are known. A) c_{n+2}+64 c_{n}=0, n=0,1,2, \ldots B) c_{n+1}+64 c_{n}=0, n=0,1,2, \ldots C) (n+1)(n+2) c_{n+2}+64 c_{n}=0, n=0,1,2, \ldots D) n(n+1) c_{n+1}+64 c_{n}=0, n=0,1,2, \ldots <div style=padding-top: 35px>$
What is the recurrence relation for the coefficientsC_n ? Assume that C₀ and C₁ are known.

c_{n+2}+64 c_{n}=0, n=0,1,2, \ldots

c_{n+1}+64 c_{n}=0, n=0,1,2, \ldots

(n+1)(n+2) c_{n+2}+64 c_{n}=0, n=0,1,2, \ldots

n(n+1) c_{n+1}+64 c_{n}=0, n=0,1,2, \ldots

سؤال

Consider the second-order differential equation

+ 49y = 0.
Assume a solution of this equation can be represented as a power series

Write down the explicit formulas for the coefficients C_n

سؤال

Consider the second-order differential equation

+ 100y = 0.
Assume a solution of this equation can be represented as a power series

Assume the solution of the given differential equation is written as

Identify elementary functions for y₁ (x) and y₂ (x).
y₁ (x) = ________
y₂ (x) = ________

سؤال

Consider the second-order differential equation $Consider the second-order differential equation - 4x + y = 0. Assume a solution of this equation can be represented as a power series What is the recurrence relation for the coefficients Cn? Assume that C0 and C1 are known A) c_{n+2}-(4 n-1) c_{n}=0, n=0,1,2, \ldots B) (n+1)(n+2) c_{n+2}-(4 n-1) c_{n}=0, n=0,1,2, \ldots C) (n+1) c_{n+1}-(4 n-1) c_{n}=0, n=0,1,2, \ldots D) c_{n+1}-(4 n-1) c_{n}=0, n=0,1,2, \ldots <div style=padding-top: 35px>$ - 4x $Consider the second-order differential equation - 4x + y = 0. Assume a solution of this equation can be represented as a power series What is the recurrence relation for the coefficients Cn? Assume that C0 and C1 are known A) c_{n+2}-(4 n-1) c_{n}=0, n=0,1,2, \ldots B) (n+1)(n+2) c_{n+2}-(4 n-1) c_{n}=0, n=0,1,2, \ldots C) (n+1) c_{n+1}-(4 n-1) c_{n}=0, n=0,1,2, \ldots D) c_{n+1}-(4 n-1) c_{n}=0, n=0,1,2, \ldots <div style=padding-top: 35px>$ + y = 0.
Assume a solution of this equation can be represented as a power series $Consider the second-order differential equation - 4x + y = 0. Assume a solution of this equation can be represented as a power series What is the recurrence relation for the coefficients Cn? Assume that C0 and C1 are known A) c_{n+2}-(4 n-1) c_{n}=0, n=0,1,2, \ldots B) (n+1)(n+2) c_{n+2}-(4 n-1) c_{n}=0, n=0,1,2, \ldots C) (n+1) c_{n+1}-(4 n-1) c_{n}=0, n=0,1,2, \ldots D) c_{n+1}-(4 n-1) c_{n}=0, n=0,1,2, \ldots <div style=padding-top: 35px>$
What is the recurrence relation for the coefficients C_n? Assume that C₀ and C₁ are known

c_{n+2}-(4 n-1) c_{n}=0, n=0,1,2, \ldots

(n+1)(n+2) c_{n+2}-(4 n-1) c_{n}=0, n=0,1,2, \ldots

(n+1) c_{n+1}-(4 n-1) c_{n}=0, n=0,1,2, \ldots

c_{n+1}-(4 n-1) c_{n}=0, n=0,1,2, \ldots

سؤال

Consider the second-order differential equation

Assume a solution of this equation can be represented as a power series

Write down the following explicit formulas for the coefficients C_n:
C_2n= ________, n = 0, 1, 2, ...
C_2n+1= ________, n = 0, 1, 2, ...

سؤال

Consider the first-order differential equation $Consider the first-order differential equation - 5y = 0. Assume a solution of this equation can be represented as a power series What is the recurrence relation for the coefficients Cn? Assume that C0 is known A) c_{n+1}-5 c_{n}=0, n=0,1,2, \ldots B) (n+1)(n+2) c_{n+1}-5 c_{n}=0, n=0,1,2, \ldots C) (n+1) c_{n+1}+5 c_{n}=0, n=0,1,2, \ldots D) (n+1) c_{n+1}-5 c_{n}=0, n=0,1,2, \ldots <div style=padding-top: 35px>$ - 5y = 0.
Assume a solution of this equation can be represented as a power series $Consider the first-order differential equation - 5y = 0. Assume a solution of this equation can be represented as a power series What is the recurrence relation for the coefficients Cn? Assume that C0 is known A) c_{n+1}-5 c_{n}=0, n=0,1,2, \ldots B) (n+1)(n+2) c_{n+1}-5 c_{n}=0, n=0,1,2, \ldots C) (n+1) c_{n+1}+5 c_{n}=0, n=0,1,2, \ldots D) (n+1) c_{n+1}-5 c_{n}=0, n=0,1,2, \ldots <div style=padding-top: 35px>$
What is the recurrence relation for the coefficients C_n? Assume that C₀ is known

c_{n+1}-5 c_{n}=0, n=0,1,2, \ldots

(n+1)(n+2) c_{n+1}-5 c_{n}=0, n=0,1,2, \ldots

(n+1) c_{n+1}+5 c_{n}=0, n=0,1,2, \ldots

(n+1) c_{n+1}-5 c_{n}=0, n=0,1,2, \ldots

سؤال

Consider the first-order differential equation

- 7y = 0.
Assume a solution of this equation can be represented as a power series

Write down the following explicit formula for the coefficients C_n

= , n = 0, 1, 2, ...

سؤال

Consider the first-order differential equation $Consider the first-order differential equation - 7y = 0. Assume a solution of this equation can be represented as a power series Which of these elementary functions is equal to the power series representation of the solution? A) y=2^{c_{0}} e^{x} B) y=c_{0} e^{2 x} C) y=c_{0} e^{x} D) y=c_{0} e^{\frac{x}{2}} E) y=\frac{c_{0}}{2} e^{x} <div style=padding-top: 35px>$ - 7y = 0.
Assume a solution of this equation can be represented as a power series $Consider the first-order differential equation - 7y = 0. Assume a solution of this equation can be represented as a power series Which of these elementary functions is equal to the power series representation of the solution? A) y=2^{c_{0}} e^{x} B) y=c_{0} e^{2 x} C) y=c_{0} e^{x} D) y=c_{0} e^{\frac{x}{2}} E) y=\frac{c_{0}}{2} e^{x} <div style=padding-top: 35px>$
Which of these elementary functions is equal to the power series representation of the solution?

y=2^{c_{0}} e^{x}

y=c_{0} e^{2 x}

y=c_{0} e^{x}

y=c_{0} e^{\frac{x}{2}}

y=\frac{c_{0}}{2} e^{x}

سؤال

Consider the first-order differential equation $Consider the first-order differential equation Assume a solution of this equation can be represented as a power series . Assume that C0 is known. Which of these power series equals y(x)? A) \sum_{n=0}^{\infty} \frac{17 c_{0}}{3(n !)^{2}} x^{3 n} B) \sum_{n=0}^{\infty} \frac{c_{0} 17^{n}}{n ! 3} x^{3 n} C) \sum_{n=0}^{\infty} \frac{17 c_{0}}{3^{n} n !} x^{3 n} D) \sum_{n=0}^{\infty} \frac{17 c_{0}}{3^{n}(n !)^{2}} x^{3 n} <div style=padding-top: 35px>$
Assume a solution of this equation can be represented as a power series $Consider the first-order differential equation Assume a solution of this equation can be represented as a power series . Assume that C0 is known. Which of these power series equals y(x)? A) \sum_{n=0}^{\infty} \frac{17 c_{0}}{3(n !)^{2}} x^{3 n} B) \sum_{n=0}^{\infty} \frac{c_{0} 17^{n}}{n ! 3} x^{3 n} C) \sum_{n=0}^{\infty} \frac{17 c_{0}}{3^{n} n !} x^{3 n} D) \sum_{n=0}^{\infty} \frac{17 c_{0}}{3^{n}(n !)^{2}} x^{3 n} <div style=padding-top: 35px>$ .
Assume that C₀ is known.
Which of these power series equals y(x)?

\sum_{n=0}^{\infty} \frac{17 c_{0}}{3(n !)^{2}} x^{3 n}

\sum_{n=0}^{\infty} \frac{c_{0} 17^{n}}{n ! 3} x^{3 n}

\sum_{n=0}^{\infty} \frac{17 c_{0}}{3^{n} n !} x^{3 n}

\sum_{n=0}^{\infty} \frac{17 c_{0}}{3^{n}(n !)^{2}} x^{3 n}

سؤال

Consider the first-order differential equation

Assume a solution of this equation can be represented as a power series

Assume that C₀ is known.
Identify an elementary function equal to y(x).

سؤال

Consider the first-order differential equation

.
Assume a solution of this equation can be represented as a power series

.
Write down the following explicit formulas for the coefficients C_n

سؤال

Consider this initial value problem: $Consider this initial value problem: . Assume a solution of this equation can be represented as a power series . Express the solution y(x) as an elementary function. A) y(x)=e^{\frac{(9 x)^{2}}{2}} B) y(x)=e^{\frac{9}{2} x^{2}} C) y(x)=9 e^{\frac{x^{2}}{2}} D) y(x)=\frac{9}{2} e^{x^{2}} <div style=padding-top: 35px>$ .
Assume a solution of this equation can be represented as a power series $Consider this initial value problem: . Assume a solution of this equation can be represented as a power series . Express the solution y(x) as an elementary function. A) y(x)=e^{\frac{(9 x)^{2}}{2}} B) y(x)=e^{\frac{9}{2} x^{2}} C) y(x)=9 e^{\frac{x^{2}}{2}} D) y(x)=\frac{9}{2} e^{x^{2}} <div style=padding-top: 35px>$ .
Express the solution y(x) as an elementary function.

y(x)=e^{\frac{(9 x)^{2}}{2}}

y(x)=e^{\frac{9}{2} x^{2}}

y(x)=9 e^{\frac{x^{2}}{2}}

y(x)=\frac{9}{2} e^{x^{2}}

سؤال

Consider the first-order differential equation $Consider the first-order differential equation . - 7xy = 0. Assume a solution of this equation can be represented as a power series . What is the recurrence relation for the coefficients Cn ? Assume that C0 is known. A) c_{1}=0, n c_{n+1}=7 c_{n-1}, n=1,2, \ldots B) c_{0}=0,(n+1) c_{n}=7 c_{n-1}, n=1,2, \ldots C) c_{0}=0,(n+1) c_{n+1}=7 c_{n-1}, n=1,2, \ldots D) c_{0}=0,(n+1) c_{n+1}=7 c_{n}, n=0,1,2, \ldots E) c_{1}=0,(n+1) c_{n+1}=7 c_{n-1}, n=1,2, \ldots <div style=padding-top: 35px>$ . - 7xy = 0.
Assume a solution of this equation can be represented as a power series $Consider the first-order differential equation . - 7xy = 0. Assume a solution of this equation can be represented as a power series . What is the recurrence relation for the coefficients Cn ? Assume that C0 is known. A) c_{1}=0, n c_{n+1}=7 c_{n-1}, n=1,2, \ldots B) c_{0}=0,(n+1) c_{n}=7 c_{n-1}, n=1,2, \ldots C) c_{0}=0,(n+1) c_{n+1}=7 c_{n-1}, n=1,2, \ldots D) c_{0}=0,(n+1) c_{n+1}=7 c_{n}, n=0,1,2, \ldots E) c_{1}=0,(n+1) c_{n+1}=7 c_{n-1}, n=1,2, \ldots <div style=padding-top: 35px>$ .
What is the recurrence relation for the coefficients C_n ? Assume that C₀ is known.

c_{1}=0, n c_{n+1}=7 c_{n-1}, n=1,2, \ldots

c_{0}=0,(n+1) c_{n}=7 c_{n-1}, n=1,2, \ldots

c_{0}=0,(n+1) c_{n+1}=7 c_{n-1}, n=1,2, \ldots

c_{0}=0,(n+1) c_{n+1}=7 c_{n}, n=0,1,2, \ldots

c_{1}=0,(n+1) c_{n+1}=7 c_{n-1}, n=1,2, \ldots

سؤال

Consider the first-order differential equation $Consider the first-order differential equation - 10xy = 0. Assume a solution of this equation can be represented as a power series Express the solution y(x) as an elementary function. A) y(x)=c_{0} e^{\frac{10}{2} x^{2}} B) y(x)=c_{0} e^{(10 x)^{2}} C) y(x)=c_{1} e^{10 x} D) y(x)=c_{1} e^{10 x^{2}} E) y(x)=c_{1} e^{(10 x)^{2}} <div style=padding-top: 35px>$ - 10xy = 0.
Assume a solution of this equation can be represented as a power series $Consider the first-order differential equation - 10xy = 0. Assume a solution of this equation can be represented as a power series Express the solution y(x) as an elementary function. A) y(x)=c_{0} e^{\frac{10}{2} x^{2}} B) y(x)=c_{0} e^{(10 x)^{2}} C) y(x)=c_{1} e^{10 x} D) y(x)=c_{1} e^{10 x^{2}} E) y(x)=c_{1} e^{(10 x)^{2}} <div style=padding-top: 35px>$
Express the solution y(x) as an elementary function.

y(x)=c_{0} e^{\frac{10}{2} x^{2}}

y(x)=c_{0} e^{(10 x)^{2}}

y(x)=c_{1} e^{10 x}

y(x)=c_{1} e^{10 x^{2}}

y(x)=c_{1} e^{(10 x)^{2}}

سؤال

Consider the second-order differential equation

- 1 y = 0.
Assume a solution of this equation can be represented as a power series

Assume that C₀ and C₁ are known. Write down the following explicit formulas for the coefficients C_n

سؤال

Consider the second-order differential equation ‪

- 19x² y = 0.
Assume a solution of this equation can be represented as a power series

Write down the first four nonzero terms of the power series solution.
y(x) ≈ ________

سؤال

Consider this initial-value problem:

.
Assume a solution of this equation can be represented as a power series

.
Write down the values of these coefficients:
C₀ = ________,
C₁ = ________,
C₂ = ________,
C₃ = ________,
C₄ = ________,
C₅ = ________,
C₆ = ________

سؤال

Consider this initial-value problem:

.
Assume a solution of this equation can be represented as a power series

.
Write down the first four terms of the power series solution.

سؤال

Consider the second-order differential equation

.
Assume the solution can be expressed as a power series

. Assume C₀ = 0. Find C₁

سؤال

What is the greatest lower bound for the radius of convergence of a series solution for the second-order differential equation (x + 8)

- 7x

+ 7y = 0 about the point

سؤال

What is the greatest lower bound for the radius of convergence of a series solution for the second-order differential equation (x - 2)(x + 4)

+7(X +16)

- 8xy = 0 about the point ?

سؤال

What is a lower bound for the radius of convergence of a series solution for the second-order differential equation (x - 2)(x + 4)

+ 8(x + 7)

- 7xy = 0 about the point

سؤال

What is a lower bound for the radius of convergence of a series solution for the second-order differential equation (x - 6)(x + 12)

+ 6(x + 14)

- 2xy = 0 about the point X₀ = 11?

سؤال

What is the radius of convergence of a series solution for the second-order differential equation $What is the radius of convergence of a series solution for the second-order differential equation . A) 0 B) 1 C) . D) \infty <div style=padding-top: 35px>$ .

A) 0
B) 1
C) $What is the radius of convergence of a series solution for the second-order differential equation . A) 0 B) 1 C) . D) \infty <div style=padding-top: 35px>$ .
D)

\infty

سؤال

What is a lower bound for the radius of convergence of a series solution for the second-order differential equation

سؤال

What is the greatest lower bound of the radius of convergence of a series solution for the second-order differential equation $What is the greatest lower bound of the radius of convergence of a series solution for the second-order differential equation . A) \sqrt{15} B) \frac{1}{4} C) \frac{\sqrt{15}}{4} D) \frac{1}{2} <div style=padding-top: 35px>$ .

\sqrt{15}

\frac{1}{4}

\frac{\sqrt{15}}{4}

\frac{1}{2}

سؤال

Which of the following pairs forms a fundamental set of solutions of the Cauchy Euler differential equation $Which of the following pairs forms a fundamental set of solutions of the Cauchy Euler differential equation . A) \left\{x^{-3}, x^{3}\right\} B) \left\{x^{3}, x^{6}\right\} C) \left\{x^{3}, x^{3} \ln x\right\} D) \left\{x^{-3}, x^{-3} \ln x\right\} E) \left\{x^{3} \cos (\ln x), x^{3} \sin (\ln x)\right\} <div style=padding-top: 35px>$ .

\left\{x^{-3}, x^{3}\right\}

\left\{x^{3}, x^{6}\right\}

\left\{x^{3}, x^{3} \ln x\right\}

\left\{x^{-3}, x^{-3} \ln x\right\}

\left\{x^{3} \cos (\ln x), x^{3} \sin (\ln x)\right\}

سؤال

Which of the following pairs forms a fundamental set of solutions of the Cauchy Euler differential equation $Which of the following pairs forms a fundamental set of solutions of the Cauchy Euler differential equation . A) \left\{x^{-5}, x^{-5} \cos (\ln x)\right\} B) \left\{x^{5}, x^{-5}\right\} C) \left\{x^{5}, x^{5} \ln x\right\} D) \left\{x^{-5}, x^{-5} \ln x\right\} E) \left\{x^{5}, x^{5} \cos (\ln x)\right\} <div style=padding-top: 35px>$ .

\left\{x^{-5}, x^{-5} \cos (\ln x)\right\}

\left\{x^{5}, x^{-5}\right\}

\left\{x^{5}, x^{5} \ln x\right\}

\left\{x^{-5}, x^{-5} \ln x\right\}

\left\{x^{5}, x^{5} \cos (\ln x)\right\}

سؤال

Which of the following pairs forms a fundamental set of solutions of the Cauchy Euler differential equation $Which of the following pairs forms a fundamental set of solutions of the Cauchy Euler differential equation . A) \{\cos (6 \ln x), \sin (6 \ln x)\} B) \left\{x^{6} \cos (\ln x), x^{6} \sin (\ln x)\right\} C) \{\ln (\cos (6 x)), \ln (\sin (6 x))\} D) \left\{x^{-6}, x^{6}\right\} E) \{\cos (\ln (6 x)), \sin (\ln (6 x))\} <div style=padding-top: 35px>$ .

\{\cos (6 \ln x), \sin (6 \ln x)\}

\left\{x^{6} \cos (\ln x), x^{6} \sin (\ln x)\right\}

\{\ln (\cos (6 x)), \ln (\sin (6 x))\}

\left\{x^{-6}, x^{6}\right\}

\{\cos (\ln (6 x)), \sin (\ln (6 x))\}

سؤال

Find the general solution of the Cauchy Euler differential equation $Find the general solution of the Cauchy Euler differential equation . A) y=C_{1} x^{-\frac{1}{2}}+C_{2} x^{\frac{1}{2}} B) y=C_{1} x^{\frac{1}{2}}+C_{2} x^{\frac{1}{2}} \ln x C) y=C_{1} x^{-\frac{1}{2}}+C_{2} x^{-\frac{1}{2}} \ln x D) y=x^{-\frac{1}{2}}\left(C_{1} \sin \frac{1}{2} \ln x+C_{2} \cos \frac{1}{2} \ln x\right) E) y=x^{-\frac{1}{2}}\left(C_{1} \sin \ln \frac{1}{2} x+C_{2} \cos \ln \frac{1}{2} x\right) F) y=x^{\frac{1}{2}}\left(C_{1} \sin -\frac{1}{2} \ln x+C_{2} \cos -\frac{1}{2} \ln x\right) <div style=padding-top: 35px>$ .

y=C_{1} x^{-\frac{1}{2}}+C_{2} x^{\frac{1}{2}}

y=C_{1} x^{\frac{1}{2}}+C_{2} x^{\frac{1}{2}} \ln x

y=C_{1} x^{-\frac{1}{2}}+C_{2} x^{-\frac{1}{2}} \ln x

y=x^{-\frac{1}{2}}\left(C_{1} \sin \frac{1}{2} \ln x+C_{2} \cos \frac{1}{2} \ln x\right)

y=x^{-\frac{1}{2}}\left(C_{1} \sin \ln \frac{1}{2} x+C_{2} \cos \ln \frac{1}{2} x\right)

y=x^{\frac{1}{2}}\left(C_{1} \sin -\frac{1}{2} \ln x+C_{2} \cos -\frac{1}{2} \ln x\right)

سؤال

Find the general solution of the Cauchy Euler differential equation $Find the general solution of the Cauchy Euler differential equation . A) y=C_{1} x^{-\frac{8}{5}}+C_{2} x^{-\frac{8}{3}} B) y=C_{1} x^{\frac{8}{5}}+C_{2} x^{\frac{8}{3}} C) y=C_{1} x^{\frac{5}{8}}+C_{2} x^{\frac{5}{8}} \ln x D) y=C_{1} x^{\frac{8}{3}}+C_{2} x^{\frac{8}{3}} \ln x E) y=C_{1} x^{\frac{8}{5}}+C_{2} x^{-\frac{8}{3}} <div style=padding-top: 35px>$ .

y=C_{1} x^{-\frac{8}{5}}+C_{2} x^{-\frac{8}{3}}

y=C_{1} x^{\frac{8}{5}}+C_{2} x^{\frac{8}{3}}

y=C_{1} x^{\frac{5}{8}}+C_{2} x^{\frac{5}{8}} \ln x

y=C_{1} x^{\frac{8}{3}}+C_{2} x^{\frac{8}{3}} \ln x

y=C_{1} x^{\frac{8}{5}}+C_{2} x^{-\frac{8}{3}}

سؤال

Find the general solution of the Cauchy Euler differential equation $Find the general solution of the Cauchy Euler differential equation . A) y=C_{1} x^{-2}+C_{2} x^{-7} B) y=C_{1} x^{2}+C_{2} x^{-7} C) y=C_{1} x^{-2}+C_{2} x^{7} D) y=C_{1} x^{2}+C_{2} x^{7} <div style=padding-top: 35px>$ .

y=C_{1} x^{-2}+C_{2} x^{-7}

y=C_{1} x^{2}+C_{2} x^{-7}

y=C_{1} x^{-2}+C_{2} x^{7}

y=C_{1} x^{2}+C_{2} x^{7}

سؤال

Solve this initial value problem: $Solve this initial value problem: . A) y=\frac{25}{9} x^{6}+\frac{25}{9} x^{-3} B) y=\frac{25}{9} x^{-6}+\frac{25}{9} x^{3} C) y=-\frac{25}{3} x^{6}-\frac{40}{3} x^{-3} D) y=-\frac{25}{3} x^{-6}-\frac{40}{3} x^{3} <div style=padding-top: 35px>$ .

y=\frac{25}{9} x^{6}+\frac{25}{9} x^{-3}

y=\frac{25}{9} x^{-6}+\frac{25}{9} x^{3}

y=-\frac{25}{3} x^{6}-\frac{40}{3} x^{-3}

y=-\frac{25}{3} x^{-6}-\frac{40}{3} x^{3}

سؤال

Solve this initial value problem:

سؤال

Find the general solution of the Cauchy Euler differential equation $Find the general solution of the Cauchy Euler differential equation . A) y=C_{1}(x-3)^{5}+C_{2}(x-3)^{5} \ln x B) y=C_{1}(x-3)^{-5}+C_{2}(x-3)^{5} C) y=C_{1}(x-3)^{-5}+C_{2}(x-3)^{-5} \ln x D) y=C_{1}(x-3)^{5}+C_{2}(x-3)^{10} <div style=padding-top: 35px>$ .

y=C_{1}(x-3)^{5}+C_{2}(x-3)^{5} \ln x

y=C_{1}(x-3)^{-5}+C_{2}(x-3)^{5}

y=C_{1}(x-3)^{-5}+C_{2}(x-3)^{-5} \ln x

y=C_{1}(x-3)^{5}+C_{2}(x-3)^{10}

سؤال

Find the general solution of the Cauchy Euler differential equation $Find the general solution of the Cauchy Euler differential equation . A) y=(x+1)^{-7}\left(C_{1}+C_{2} \ln x\right) B) y=C_{1}(x+1)^{-7}+C_{2}(x+1)^{7} C) y=(x+1)^{-7}\left(C_{1} \sin (\ln x)+C_{2} \cos (\ln x)\right) D) y=(x+1)^{7}\left(C_{1}+C_{2} \ln x\right) E) y=(x+1)^{7}\left(C_{1} \ln (\sin x)+C_{2} \ln (\cos x)\right) <div style=padding-top: 35px>$ .

y=(x+1)^{-7}\left(C_{1}+C_{2} \ln x\right)

y=C_{1}(x+1)^{-7}+C_{2}(x+1)^{7}

y=(x+1)^{-7}\left(C_{1} \sin (\ln x)+C_{2} \cos (\ln x)\right)

y=(x+1)^{7}\left(C_{1}+C_{2} \ln x\right)

y=(x+1)^{7}\left(C_{1} \ln (\sin x)+C_{2} \ln (\cos x)\right)

سؤال

Consider the Bessel equation of order .
Which of these statements is true?

A) x = 7 is a regular singular point.
B) x = 0 is a regular singular point.
C) x = 0 is an irregular singular point.
D) There are no singular points.

سؤال

Consider the Legendre equation: .
Which of these statements is true?

A) x = 1 is a regular singular point and x = -1 is an irregular singular point.
B) x = 1 is an irregular singular point and x = -1 is a regular singular point.
C) Both x = 1 and x = -1 are regular singular points.
D) Both x = 1 and x = -1 are irregular singular points.

سؤال

Consider the second-order differential equation .
Which of these statements is true?

A) x = 0 is a regular singular point and x = 5 is an irregular singular point.
B) x = 0 is an irregular singular point and x = 5 is a regular singular point.
C) Both x = 0 and x = 5 are regular singular points.
D) Both x = 0 and x = 5 are irregular singular points.

سؤال

Consider the second-order differential equation: .
Which of these statements is true?

A) x = 9 and x = -9 are both regular singular points.
B) x = 9 and x = -9 are both irregular singular points.
C) x = 0 and x = 9 are regular singular points, and x = -9 is an irregular singular point.
D) x = 0 and x = -9 are regular singular points, and x = 9 is an irregular singular point.

سؤال

Consider the second-order differential equation .
Which of these statements is true?

A) x = 0 is a regular singular point.
B) x = -8 is a regular singular point.
C) x = -8 is an irregular singular point.
D) There are no singular points.

سؤال

x = 0 is a regular singular point for the second-order differential equation

سؤال

Consider the second-order differential equation .
Which of these statements is true?

A) x = 4 and x = -4 are both irregular singular points.
B) x = 4 and x = -4 are both regular singular points.
C) x = -4 is a regular singular point and x = 4 is an irregular singular point.
D) x = 4 is a regular singular point and x = -4 is an irregular singular point.

سؤال

Consider the second-order differential equation: $Consider the second-order differential equation: . Why is C0 = 0 a regular singular point? A) The functions x^{2} \cdot \frac{7 x(x+1)}{5 x^{2}} and x \cdot\left(-\frac{7}{5 x^{2}}\right) both have convergent Taylor series expansions about 0 . B) The functions x \cdot \frac{7 x(x+1)}{5 x^{2}} and x^{2} \cdot\left(-\frac{7}{5 x^{2}}\right) both have convergent Taylor series expansions about 0 . C) \lim _{x \rightarrow 0} x \cdot\left(-\frac{7}{5 x^{2}}\right)=\infty D) \lim _{x \rightarrow 0} x \cdot\left(-\frac{7}{5 x^{2}}\right) \neq 0 <div style=padding-top: 35px>$ .
Why is C₀ = 0 a regular singular point?

A) The functions

x^{2} \cdot \frac{7 x(x+1)}{5 x^{2}}

and

x \cdot\left(-\frac{7}{5 x^{2}}\right)

both have convergent Taylor series expansions about 0 .
B) The functions

x \cdot \frac{7 x(x+1)}{5 x^{2}}

and

x^{2} \cdot\left(-\frac{7}{5 x^{2}}\right)

both have convergent Taylor series expansions about 0 .
C)

\lim _{x \rightarrow 0} x \cdot\left(-\frac{7}{5 x^{2}}\right)=\infty

\lim _{x \rightarrow 0} x \cdot\left(-\frac{7}{5 x^{2}}\right) \neq 0

سؤال

Consider the second-order differential equation: .
Which of these is the indicial equation?

A) (3r - 1)(r + 5) = 0
B) (3r + 1)(r - 5) = 0
C) (3r + 5)(r - 1) = 0
D) (3r - 5)(r + 1) = 0

سؤال

Consider the second-order differential equation: $Consider the second-order differential equation: . Which of these is the recurrence relation for the coefficients? A) a_{n}=\frac{-2(n+r-1) a_{n-1}}{(2(n+r)+5)(n+r+1)}, n \geq 1 B) a_{n}=\frac{2(n+r-1) a_{n-1}}{(2(n+r)-5)(n+r+1)}, n \geq 1 C) a_{n}=\frac{-2(n+r-1) a_{n-1}}{(2(n+r)-1)(n+r+5)}, n \geq 1 D) a_{n}=\frac{2(n+r-1) a_{n-1}}{(2(n+r)+1)(n+r-5)}, n \geq 1 <div style=padding-top: 35px>$ .
Which of these is the recurrence relation for the coefficients?

a_{n}=\frac{-2(n+r-1) a_{n-1}}{(2(n+r)+5)(n+r+1)}, n \geq 1

a_{n}=\frac{2(n+r-1) a_{n-1}}{(2(n+r)-5)(n+r+1)}, n \geq 1

a_{n}=\frac{-2(n+r-1) a_{n-1}}{(2(n+r)-1)(n+r+5)}, n \geq 1

a_{n}=\frac{2(n+r-1) a_{n-1}}{(2(n+r)+1)(n+r-5)}, n \geq 1

سؤال

Consider the second-order differential equation:

.
Write out the first three terms of the solution corresponding to the positive root of the indicial equation.
Y₁ (x) ≈ ________

سؤال

Consider the second-order differential equation:

.
Write out the first three terms of the solution corresponding to the nonpositive root of the indicial equation.
Y₂ (x) ≈ ________

سؤال

Consider the second-order differential equation:

.
The general solution of the differential equation is

.
are arbitrary real constants.

سؤال

Consider the Bessel equation of order $Consider the Bessel equation of order . Suppose the method of Frobenius is used to determine a power series solution of the form . Of this differential equation. Assume a0 \neq 0. Which of these is the indicial equation? A) r2 - 36 = 0 B) r2- 6 = 0 C) r2+ 6 = 0 D) r2+ 36 = 0 <div style=padding-top: 35px>$ .
Suppose the method of Frobenius is used to determine a power series solution of the form $Consider the Bessel equation of order . Suppose the method of Frobenius is used to determine a power series solution of the form . Of this differential equation. Assume a0 \neq 0. Which of these is the indicial equation? A) r2 - 36 = 0 B) r2- 6 = 0 C) r2+ 6 = 0 D) r2+ 36 = 0 <div style=padding-top: 35px>$ .
Of this differential equation. Assume a₀ $\neq$ 0.
Which of these is the indicial equation?

A) r² - 36 = 0
B) r²- 6 = 0
C) r²+ 6 = 0
D) r²+ 36 = 0

سؤال

Consider the Bessel equation of order $Consider the Bessel equation of order . Suppose the method of Frobenius is used to determine a power series solution of the form . Of this differential equation. Assume a0 \neq 0. Which of these is the recurrence relation for the coefficients? A) a_{1}=0, a_{n+2}=\frac{-a_{n}}{(r+n-2)^{2}+16}, n \geq 0 B) a_{1}=0, a_{n+2}=\frac{-a_{n}}{(r+n+2)^{2}-16}, n \geq 0 C) a_{1}=1, a_{n+2}=\frac{-a_{n}}{(r+n-2)^{2}+16}, n \geq 0 D) a_{1}=1, a_{n+2}=\frac{-a_{n}}{(r+n+2)^{2}-16}, n \geq 0 <div style=padding-top: 35px>$ .
Suppose the method of Frobenius is used to determine a power series solution of the form $Consider the Bessel equation of order . Suppose the method of Frobenius is used to determine a power series solution of the form . Of this differential equation. Assume a0 \neq 0. Which of these is the recurrence relation for the coefficients? A) a_{1}=0, a_{n+2}=\frac{-a_{n}}{(r+n-2)^{2}+16}, n \geq 0 B) a_{1}=0, a_{n+2}=\frac{-a_{n}}{(r+n+2)^{2}-16}, n \geq 0 C) a_{1}=1, a_{n+2}=\frac{-a_{n}}{(r+n-2)^{2}+16}, n \geq 0 D) a_{1}=1, a_{n+2}=\frac{-a_{n}}{(r+n+2)^{2}-16}, n \geq 0 <div style=padding-top: 35px>$ .
Of this differential equation. Assume a₀ $\neq$ 0.
Which of these is the recurrence relation for the coefficients?

a_{1}=0, a_{n+2}=\frac{-a_{n}}{(r+n-2)^{2}+16}, n \geq 0

a_{1}=0, a_{n+2}=\frac{-a_{n}}{(r+n+2)^{2}-16}, n \geq 0

a_{1}=1, a_{n+2}=\frac{-a_{n}}{(r+n-2)^{2}+16}, n \geq 0

a_{1}=1, a_{n+2}=\frac{-a_{n}}{(r+n+2)^{2}-16}, n \geq 0

سؤال

Consider the Bessel equation of order $Consider the Bessel equation of order . Suppose the method of Frobenius is used to determine a power series solution of the form . Of this differential equation. Assume a0 \neq 0. Which of these is the explicit formula for the coefficients corresponding to the positive root of the indicial equation? A) a_{2 n}=0 and a_{2 n+1}=(-1)^{n} \cdot \frac{a_{0} \cdot 4 !}{2^{n+1}(n+1) !(n+4) !}, n \geq 1 B) a_{2 n}=0 and a_{2 n+1}=(-1)^{n} \cdot \frac{a_{0} \cdot 4 !}{2^{2 n} n !(n+4) !}, n \geq 1 C) a_{2 n+1}=0 and a_{2 n}=(-1)^{n-1} \cdot \frac{a_{0} \cdot 4 !}{2^{n} n !(n+4) !}, n \geq 1 D) a_{2 n+1}=0 and a_{2 n}=(-1)^{n} \cdot \frac{a_{0} \cdot 4 !}{2^{2 n} n !(n+4) !}, n \geq 1 <div style=padding-top: 35px>$ .
Suppose the method of Frobenius is used to determine a power series solution of the form $Consider the Bessel equation of order . Suppose the method of Frobenius is used to determine a power series solution of the form . Of this differential equation. Assume a0 \neq 0. Which of these is the explicit formula for the coefficients corresponding to the positive root of the indicial equation? A) a_{2 n}=0 and a_{2 n+1}=(-1)^{n} \cdot \frac{a_{0} \cdot 4 !}{2^{n+1}(n+1) !(n+4) !}, n \geq 1 B) a_{2 n}=0 and a_{2 n+1}=(-1)^{n} \cdot \frac{a_{0} \cdot 4 !}{2^{2 n} n !(n+4) !}, n \geq 1 C) a_{2 n+1}=0 and a_{2 n}=(-1)^{n-1} \cdot \frac{a_{0} \cdot 4 !}{2^{n} n !(n+4) !}, n \geq 1 D) a_{2 n+1}=0 and a_{2 n}=(-1)^{n} \cdot \frac{a_{0} \cdot 4 !}{2^{2 n} n !(n+4) !}, n \geq 1 <div style=padding-top: 35px>$ .
Of this differential equation. Assume a₀ $\neq$ 0.
Which of these is the explicit formula for the coefficients corresponding to the positive root of the indicial equation?

a_{2 n}=0

and

a_{2 n+1}=(-1)^{n} \cdot \frac{a_{0} \cdot 4 !}{2^{n+1}(n+1) !(n+4) !}, n \geq 1

a_{2 n}=0

and

a_{2 n+1}=(-1)^{n} \cdot \frac{a_{0} \cdot 4 !}{2^{2 n} n !(n+4) !}, n \geq 1

a_{2 n+1}=0

and

a_{2 n}=(-1)^{n-1} \cdot \frac{a_{0} \cdot 4 !}{2^{n} n !(n+4) !}, n \geq 1

a_{2 n+1}=0

and

a_{2 n}=(-1)^{n} \cdot \frac{a_{0} \cdot 4 !}{2^{2 n} n !(n+4) !}, n \geq 1

سؤال

Consider the Bessel equation of order

.
Suppose the method of Frobenius is used to determine a power series solution of the form

.
of this differential equation. Assume a₀ ≠ 0.
Write the power series solution corresponding to the positive root of the indicial equation.
Y₁ (x) = ________

سؤال

Consider the second-order differential equation $Consider the second-order differential equation . Write the differential equation in the form . a regular singular point for this equation? A) x^{2} p(x) and x q(x) both have convergent Taylor expansions about 0 . B) \lim _{x \rightarrow 0} x^{2} p(x)=0 and \lim _{x \rightarrow 0} x q(x)=\infty C) \lim _{x \rightarrow 0} x p(x) is finite and \lim _{x \rightarrow 0} x^{2} \gamma(x)=\infty D) \lim _{x \rightarrow 0} x p(x) is finite and x^{2} \gamma(x) has a convergent Taylor expansion about 0 . <div style=padding-top: 35px>$ .
Write the differential equation in the form $Consider the second-order differential equation . Write the differential equation in the form . a regular singular point for this equation? A) x^{2} p(x) and x q(x) both have convergent Taylor expansions about 0 . B) \lim _{x \rightarrow 0} x^{2} p(x)=0 and \lim _{x \rightarrow 0} x q(x)=\infty C) \lim _{x \rightarrow 0} x p(x) is finite and \lim _{x \rightarrow 0} x^{2} \gamma(x)=\infty D) \lim _{x \rightarrow 0} x p(x) is finite and x^{2} \gamma(x) has a convergent Taylor expansion about 0 . <div style=padding-top: 35px>$ . a regular singular point for this equation?

x^{2} p(x)

and

x q(x)

both have convergent Taylor expansions about 0 .
B)

\lim _{x \rightarrow 0} x^{2} p(x)=0

and

\lim _{x \rightarrow 0} x q(x)=\infty

\lim _{x \rightarrow 0} x p(x)

is finite and

\lim _{x \rightarrow 0} x^{2} \gamma(x)=\infty

\lim _{x \rightarrow 0} x p(x)

is finite and

x^{2} \gamma(x)

has a convergent Taylor expansion about 0 .

سؤال

Consider the second-order differential equation $Consider the second-order differential equation . Suppose the method of Frobineius is used to determine a power series solution of the form . Of this differential equation. Assume a0 \neq 0. Which of these is the indicial equation? A) r2+ 7r = 0 B) + 8r = 0 C) - 8r = 0 D) - 7r = 0 <div style=padding-top: 35px>$ .
Suppose the method of Frobineius is used to determine a power series solution of the form $Consider the second-order differential equation . Suppose the method of Frobineius is used to determine a power series solution of the form . Of this differential equation. Assume a0 \neq 0. Which of these is the indicial equation? A) r2+ 7r = 0 B) + 8r = 0 C) - 8r = 0 D) - 7r = 0 <div style=padding-top: 35px>$ .
Of this differential equation. Assume a₀ $\neq$ 0. Which of these is the indicial equation?

A) r²+ 7r = 0
B) $Consider the second-order differential equation . Suppose the method of Frobineius is used to determine a power series solution of the form . Of this differential equation. Assume a0 \neq 0. Which of these is the indicial equation? A) r2+ 7r = 0 B) + 8r = 0 C) - 8r = 0 D) - 7r = 0 <div style=padding-top: 35px>$ + 8r = 0
C) $Consider the second-order differential equation . Suppose the method of Frobineius is used to determine a power series solution of the form . Of this differential equation. Assume a0 \neq 0. Which of these is the indicial equation? A) r2+ 7r = 0 B) + 8r = 0 C) - 8r = 0 D) - 7r = 0 <div style=padding-top: 35px>$ - 8r = 0
D) $Consider the second-order differential equation . Suppose the method of Frobineius is used to determine a power series solution of the form . Of this differential equation. Assume a0 \neq 0. Which of these is the indicial equation? A) r2+ 7r = 0 B) + 8r = 0 C) - 8r = 0 D) - 7r = 0 <div style=padding-top: 35px>$ - 7r = 0

سؤال

Consider the second-order differential equation $Consider the second-order differential equation . Suppose the method of Frobenius is used to determine a power series solution of the form . Of this differential equation. Assume a0 \neq 0. Which of these is the indicial equation? A) r2 + r = 0 B) r2 - r = 0 C) r2 + r - 2 = 0 D) r2 - r - 2 = 0 <div style=padding-top: 35px>$ .
Suppose the method of Frobenius is used to determine a power series solution of the form $Consider the second-order differential equation . Suppose the method of Frobenius is used to determine a power series solution of the form . Of this differential equation. Assume a0 \neq 0. Which of these is the indicial equation? A) r2 + r = 0 B) r2 - r = 0 C) r2 + r - 2 = 0 D) r2 - r - 2 = 0 <div style=padding-top: 35px>$ .
Of this differential equation. Assume a₀ $\neq$ 0.
Which of these is the indicial equation?

A) r² + r = 0
B) r² - r = 0
C) r² + r - 2 = 0
D) r² - r - 2 = 0

سؤال

Consider the second-order differential equation

.
Suppose the method of Frobenius is used to determine a power series solution of the form

.
of this differential equation. Assume a₀ ≠ 0.
Using the larger root of the indicial equation, write down an explicit formula for the coefficients and the corresponding power series solution.
a_n = ________, n ≥ 1
y₁ (x) = ________

سؤال

a_{1}=0, a_{n}=-\frac{64 \cdot a_{n-2}}{2^{n}}, n \geq 2

a_{1}=1, a_{n}=\frac{64 \cdot a_{n-2}}{2^{n}}, n \geq 2

a_{1}=1, a_{n}=\frac{64 \cdot a_{n-2}}{n^{2}}, n \geq 2

a_{1}=0, a_{n}=-\frac{64 \cdot a_{n-2}}{n^{2}}, n \geq 2

a_{1}=0, a_{n}=-\frac{64 \cdot a_{n-2}}{n}, n \geq 2

سؤال

a_{2 n}=\frac{(-1)^{n} 2^{3 n}}{n !} a_{0, n} \geq 1

a_{2 n}=\frac{(-1)^{n} 2^{5 n}}{n !} a_{0}, n \geq 1

a_{2 n}=\frac{(-1)^{n} 2^{3 n}}{(n !)^{2}} a_{0}, n \geq 1

a_{2 n}=\frac{(-1)^{n} 2^{5 n}}{(n !)^{2}} a_{0}, n \geq 1

سؤال

Consider the second-order differential equation $Consider the second-order differential equation . Suppose the method of Frobenius is used to determine a power series solution of this equation. The indicial equation has r = 0 as a double root. So, one of the solutions can be represented as the power series . Assume a0 \neq 0. Assuming that a0 = 1, one solution of the given differential equation is . Assume x > 0. Which of these is a form of a second solution of the given differential equation, linearly independent to (x)? A) y_{2}(x)=y_{1}(x) \ln x+\sum_{n=1}^{\infty} a^{*}{ }_{n} x^{n} B) y_{2}(x)=y_{1}^{\prime}(x) \ln x \mid+\sum_{n=1}^{\infty} a^{*} n^{n} C) y_{2}(x)=\ln x+y_{1}(x) \cdot \sum_{n=1}^{\infty} a^{*}{ }_{n} x^{n} D) y_{2}(x)=|\ln x|+y_{1}(x) \cdot \sum_{n=1}^{\infty} a^{n}{ }_{n} x^{n} E) y_{2}(x)=\ln x\left(y_{1}(x)+\sum_{n=1}^{\infty} a^{n}{ }_{n} x^{n}\right) <div style=padding-top: 35px>$ .
Suppose the method of Frobenius is used to determine a power series solution of this equation. The indicial equation has r = 0 as a double root. So, one of the solutions can be represented as the power series $Consider the second-order differential equation . Suppose the method of Frobenius is used to determine a power series solution of this equation. The indicial equation has r = 0 as a double root. So, one of the solutions can be represented as the power series . Assume a0 \neq 0. Assuming that a0 = 1, one solution of the given differential equation is . Assume x > 0. Which of these is a form of a second solution of the given differential equation, linearly independent to (x)? A) y_{2}(x)=y_{1}(x) \ln x+\sum_{n=1}^{\infty} a^{*}{ }_{n} x^{n} B) y_{2}(x)=y_{1}^{\prime}(x) \ln x \mid+\sum_{n=1}^{\infty} a^{*} n^{n} C) y_{2}(x)=\ln x+y_{1}(x) \cdot \sum_{n=1}^{\infty} a^{*}{ }_{n} x^{n} D) y_{2}(x)=|\ln x|+y_{1}(x) \cdot \sum_{n=1}^{\infty} a^{n}{ }_{n} x^{n} E) y_{2}(x)=\ln x\left(y_{1}(x)+\sum_{n=1}^{\infty} a^{n}{ }_{n} x^{n}\right) <div style=padding-top: 35px>$ .
Assume a₀ $\neq$ 0.
Assuming that a₀ = 1, one solution of the given differential equation is $Consider the second-order differential equation . Suppose the method of Frobenius is used to determine a power series solution of this equation. The indicial equation has r = 0 as a double root. So, one of the solutions can be represented as the power series . Assume a0 \neq 0. Assuming that a0 = 1, one solution of the given differential equation is . Assume x > 0. Which of these is a form of a second solution of the given differential equation, linearly independent to (x)? A) y_{2}(x)=y_{1}(x) \ln x+\sum_{n=1}^{\infty} a^{*}{ }_{n} x^{n} B) y_{2}(x)=y_{1}^{\prime}(x) \ln x \mid+\sum_{n=1}^{\infty} a^{*} n^{n} C) y_{2}(x)=\ln x+y_{1}(x) \cdot \sum_{n=1}^{\infty} a^{*}{ }_{n} x^{n} D) y_{2}(x)=|\ln x|+y_{1}(x) \cdot \sum_{n=1}^{\infty} a^{n}{ }_{n} x^{n} E) y_{2}(x)=\ln x\left(y_{1}(x)+\sum_{n=1}^{\infty} a^{n}{ }_{n} x^{n}\right) <div style=padding-top: 35px>$ .
Assume x > 0. Which of these is a form of a second solution of the given differential equation, linearly independent to (x)?

y_{2}(x)=y_{1}(x) \ln x+\sum_{n=1}^{\infty} a^{*}{ }_{n} x^{n}

y_{2}(x)=y_{1}^{\prime}(x) \ln x \mid+\sum_{n=1}^{\infty} a^{*} n^{n}

y_{2}(x)=\ln x+y_{1}(x) \cdot \sum_{n=1}^{\infty} a^{*}{ }_{n} x^{n}

y_{2}(x)=|\ln x|+y_{1}(x) \cdot \sum_{n=1}^{\infty} a^{n}{ }_{n} x^{n}

y_{2}(x)=\ln x\left(y_{1}(x)+\sum_{n=1}^{\infty} a^{n}{ }_{n} x^{n}\right)

سؤال

Consider the second-order differential equation $Consider the second-order differential equation . Suppose the method of Frobenius is used to determine a power series solution of this equation. The indicial equation has r = 0 as a double root. So, one of the solutions can be represented as the power series Assume a0 \neq 0. Assuming that a0 = 1, one solution of the given differential equation is Differentiating as needed, which of these relationships is correct? A) 2 y^{\prime}(x)-a_{1}^{*}-128 a_{2}^{*} x+\sum_{n=3}^{\infty}\left(n^{2} a_{n}^{*}-128 a_{n-2}^{*}\right) x^{n-1}=0 B) 2 y^{\prime}(x)+a_{1}^{*}+128 a_{2}^{*} x+\sum_{n=3}^{\infty}\left(n^{2} a_{n}^{*}+128 a_{n-2}^{*}\right) x^{n-1}=0 C) 2 y^{\prime}(x)+a_{1}^{*}-128 a_{2}^{*} x-\sum_{n=3}^{\infty}\left(n^{2} a_{n}^{*}+128 a_{n-2}^{*}\right) x^{n-1}=0 D) 2 y^{\prime}(x)+a_{1}^{*}+128 a_{2}^{*} x+\sum_{n=3}^{\infty}\left(n^{2} a_{n}^{*}-128 a_{n-2}^{*}\right) x^{n-1}=0 <div style=padding-top: 35px>$ .
Suppose the method of Frobenius is used to determine a power series solution of this equation. The indicial equation has r = 0 as a double root. So, one of the solutions can be represented as the power series $Consider the second-order differential equation . Suppose the method of Frobenius is used to determine a power series solution of this equation. The indicial equation has r = 0 as a double root. So, one of the solutions can be represented as the power series Assume a0 \neq 0. Assuming that a0 = 1, one solution of the given differential equation is Differentiating as needed, which of these relationships is correct? A) 2 y^{\prime}(x)-a_{1}^{*}-128 a_{2}^{*} x+\sum_{n=3}^{\infty}\left(n^{2} a_{n}^{*}-128 a_{n-2}^{*}\right) x^{n-1}=0 B) 2 y^{\prime}(x)+a_{1}^{*}+128 a_{2}^{*} x+\sum_{n=3}^{\infty}\left(n^{2} a_{n}^{*}+128 a_{n-2}^{*}\right) x^{n-1}=0 C) 2 y^{\prime}(x)+a_{1}^{*}-128 a_{2}^{*} x-\sum_{n=3}^{\infty}\left(n^{2} a_{n}^{*}+128 a_{n-2}^{*}\right) x^{n-1}=0 D) 2 y^{\prime}(x)+a_{1}^{*}+128 a_{2}^{*} x+\sum_{n=3}^{\infty}\left(n^{2} a_{n}^{*}-128 a_{n-2}^{*}\right) x^{n-1}=0 <div style=padding-top: 35px>$ Assume a₀ $\neq$ 0.
Assuming that a₀ = 1, one solution of the given differential equation is $Consider the second-order differential equation . Suppose the method of Frobenius is used to determine a power series solution of this equation. The indicial equation has r = 0 as a double root. So, one of the solutions can be represented as the power series Assume a0 \neq 0. Assuming that a0 = 1, one solution of the given differential equation is Differentiating as needed, which of these relationships is correct? A) 2 y^{\prime}(x)-a_{1}^{*}-128 a_{2}^{*} x+\sum_{n=3}^{\infty}\left(n^{2} a_{n}^{*}-128 a_{n-2}^{*}\right) x^{n-1}=0 B) 2 y^{\prime}(x)+a_{1}^{*}+128 a_{2}^{*} x+\sum_{n=3}^{\infty}\left(n^{2} a_{n}^{*}+128 a_{n-2}^{*}\right) x^{n-1}=0 C) 2 y^{\prime}(x)+a_{1}^{*}-128 a_{2}^{*} x-\sum_{n=3}^{\infty}\left(n^{2} a_{n}^{*}+128 a_{n-2}^{*}\right) x^{n-1}=0 D) 2 y^{\prime}(x)+a_{1}^{*}+128 a_{2}^{*} x+\sum_{n=3}^{\infty}\left(n^{2} a_{n}^{*}-128 a_{n-2}^{*}\right) x^{n-1}=0 <div style=padding-top: 35px>$
Differentiating as needed, which of these relationships is correct?

2 y^{\prime}(x)-a_{1}^{*}-128 a_{2}^{*} x+\sum_{n=3}^{\infty}\left(n^{2} a_{n}^{*}-128 a_{n-2}^{*}\right) x^{n-1}=0

2 y^{\prime}(x)+a_{1}^{*}+128 a_{2}^{*} x+\sum_{n=3}^{\infty}\left(n^{2} a_{n}^{*}+128 a_{n-2}^{*}\right) x^{n-1}=0

2 y^{\prime}(x)+a_{1}^{*}-128 a_{2}^{*} x-\sum_{n=3}^{\infty}\left(n^{2} a_{n}^{*}+128 a_{n-2}^{*}\right) x^{n-1}=0

2 y^{\prime}(x)+a_{1}^{*}+128 a_{2}^{*} x+\sum_{n=3}^{\infty}\left(n^{2} a_{n}^{*}-128 a_{n-2}^{*}\right) x^{n-1}=0

سؤال

Consider the second-order differential equation

.
Suppose the method of Frobenius is used to determine a power series solution of this equation. The indicial equation has r = 0 as a double root. So, one of the solutions can be represented as the power series

. Assume a₀ ≠ 0.
Assuming that a₀= 1, one solution of the given differential equation is

Assuming that

are known, what is the radius of convergence of the power series of the second solution Y₂ (x)?

سؤال

Consider the second-order differential equation $Consider the second-order differential equation . Using the method of Frobenius, which of these is the general solution of this differential equation? Assume are arbitrary real constants. A) y(x)=a_{0}+a_{0}^{*}\left(x \ln x+\sum_{n=1}^{\infty} \frac{(-1)^{n} x^{n+1}}{n \cdot n !}\right) B) y(x)=a_{0} x+a_{0}^{*}\left(x \ln x+\sum_{n=1}^{\infty} \frac{(-1)^{n} x^{n+1}}{n \cdot n !}\right) C) y(x)=a_{0}+a^{*}{ }_{0}^{x}\left[\ln x+\sum_{n=1}^{\infty} \frac{(-1)^{n} x^{n+1}}{n \cdot n !}\right) D) y(x)=a_{0}+a_{0}^{*} \ln x\left(1+\sum_{n=1}^{\infty} \frac{(-1)^{n} x^{n+1}}{n \cdot n !}\right) <div style=padding-top: 35px>$ .
Using the method of Frobenius, which of these is the general solution of this differential equation? Assume $Consider the second-order differential equation . Using the method of Frobenius, which of these is the general solution of this differential equation? Assume are arbitrary real constants. A) y(x)=a_{0}+a_{0}^{*}\left(x \ln x+\sum_{n=1}^{\infty} \frac{(-1)^{n} x^{n+1}}{n \cdot n !}\right) B) y(x)=a_{0} x+a_{0}^{*}\left(x \ln x+\sum_{n=1}^{\infty} \frac{(-1)^{n} x^{n+1}}{n \cdot n !}\right) C) y(x)=a_{0}+a^{*}{ }_{0}^{x}\left[\ln x+\sum_{n=1}^{\infty} \frac{(-1)^{n} x^{n+1}}{n \cdot n !}\right) D) y(x)=a_{0}+a_{0}^{*} \ln x\left(1+\sum_{n=1}^{\infty} \frac{(-1)^{n} x^{n+1}}{n \cdot n !}\right) <div style=padding-top: 35px>$ are arbitrary real constants.

y(x)=a_{0}+a_{0}^{*}\left(x \ln x+\sum_{n=1}^{\infty} \frac{(-1)^{n} x^{n+1}}{n \cdot n !}\right)

y(x)=a_{0} x+a_{0}^{*}\left(x \ln x+\sum_{n=1}^{\infty} \frac{(-1)^{n} x^{n+1}}{n \cdot n !}\right)

y(x)=a_{0}+a^{*}{ }_{0}^{x}\left[\ln x+\sum_{n=1}^{\infty} \frac{(-1)^{n} x^{n+1}}{n \cdot n !}\right)

y(x)=a_{0}+a_{0}^{*} \ln x\left(1+\sum_{n=1}^{\infty} \frac{(-1)^{n} x^{n+1}}{n \cdot n !}\right)

سؤال

Consider the second-order differential equation .
What is the radius of convergence of the series of the general solution of the differential equation?

A) 1
B) 2
C) 4
D) ?

سؤال

Consider the second-order differential equation .
Suppose the method of Frobenius is used to determine the general solution of this differential equation.Which of these is the indicial equation about the regular singular point x = 0?

<strong>Consider the second-order differential equation . Suppose the method of Frobenius is used to determine the general solution of this differential equation.Which of these is the indicial equation about the regular singular point x = 0?</strong> A) + r+ = 0 B) + r - = 0 C) - r + = 0 D) - r - = 0 <div style=padding-top: 35px>

= 0
B)

r -

= 0
C)

r +

= 0
D)

r -

= 0

سؤال

Consider the second-order differential equation $Consider the second-order differential equation . Suppose the method of Frobenius is used to determine the general solution of this differential equation. Which of the following is the form of a pair of linearly independent solution of this differential A) y_{1}(x)=\sum_{n=0}^{\infty} a_{n} x^{n}, y_{2}(x)=x^{-\frac{1}{4}} \sum_{n=0}^{\infty} b_{n} x^{n} B) y_{1}(x)=\sum_{n=0}^{\infty} a_{n} x^{n+1}, y_{2}(x)=x^{-\frac{1}{4}} \sum_{n=0}^{\infty} b_{n} x^{n} C) y_{1}(x)=\sum_{n=0}^{\infty} a_{n} x^{n}, y_{2}(x)=x^{\frac{3}{4}} \sum_{n=0}^{\infty} b_{n} x^{n} D) y_{1}(x)=\sum_{n=0}^{\infty} a_{n} x^{n+1}, y_{2}(x)=x^{\frac{3}{4}} \sum_{n=0}^{\infty} b_{n} x^{n} E) y_{1}(x)=\ln (x) \sum_{n=0}^{\infty} a_{n} x^{n+1}, y_{2}(x)=x^{-\frac{1}{4}} \sum_{n=0}^{\infty} b_{n} x^{n} <div style=padding-top: 35px>$ .
Suppose the method of Frobenius is used to determine the general solution of this differential equation.
Which of the following is the form of a pair of linearly independent solution of this differential

y_{1}(x)=\sum_{n=0}^{\infty} a_{n} x^{n}, y_{2}(x)=x^{-\frac{1}{4}} \sum_{n=0}^{\infty} b_{n} x^{n}

y_{1}(x)=\sum_{n=0}^{\infty} a_{n} x^{n+1}, y_{2}(x)=x^{-\frac{1}{4}} \sum_{n=0}^{\infty} b_{n} x^{n}

y_{1}(x)=\sum_{n=0}^{\infty} a_{n} x^{n}, y_{2}(x)=x^{\frac{3}{4}} \sum_{n=0}^{\infty} b_{n} x^{n}

y_{1}(x)=\sum_{n=0}^{\infty} a_{n} x^{n+1}, y_{2}(x)=x^{\frac{3}{4}} \sum_{n=0}^{\infty} b_{n} x^{n}

y_{1}(x)=\ln (x) \sum_{n=0}^{\infty} a_{n} x^{n+1}, y_{2}(x)=x^{-\frac{1}{4}} \sum_{n=0}^{\infty} b_{n} x^{n}

سؤال

Consider the second-order differential equation .
Which of these is the indicial equation about the regular singular point x = 0?

A) r² - 9r - 16 = 0
B) r² - 7r + 16 = 0
C) r² + 7r + 16 = 0
D)

+ 8r - 16 = 0
E)

- 8r + 16 = 0

سؤال

Consider the second-order differential equation $Consider the second-order differential equation . Which of the following is the form of a pair of linearly independent solutions of this differential equation? A) y_{1}(x)=x^{-4} \sum_{n=0}^{\infty} a_{n} x^{n}, y_{2}(x)=\ln x\left(y_{1}(x)+x^{-4} \sum_{n=0}^{\infty} b_{n} x^{n}\right) B) y_{1}(x)=x^{4} \sum_{n=0}^{\infty} a_{n} x^{n}, y_{2}(x)=\ln x\left(y_{1}(x)+x^{4} \sum_{n=0}^{\infty} b_{n} x^{n}\right) C) y_{1}(x)=x^{-4} \sum_{n=0}^{\infty} a_{n} x^{n}, y_{2}(x)=y_{1}(x) \ln x+x^{-4} \sum_{n=0}^{\infty} b_{n} x^{n} D) \left.y_{1}(x)=x^{4} \sum_{n=0}^{\infty} a_{n} x^{n}, y_{2}(x)=y_{1} x\right) \ln x+x^{4} \sum_{n=0}^{\infty} b_{n} x^{n} <div style=padding-top: 35px>$ .
Which of the following is the form of a pair of linearly independent solutions of this differential equation?

y_{1}(x)=x^{-4} \sum_{n=0}^{\infty} a_{n} x^{n}, y_{2}(x)=\ln x\left(y_{1}(x)+x^{-4} \sum_{n=0}^{\infty} b_{n} x^{n}\right)

y_{1}(x)=x^{4} \sum_{n=0}^{\infty} a_{n} x^{n}, y_{2}(x)=\ln x\left(y_{1}(x)+x^{4} \sum_{n=0}^{\infty} b_{n} x^{n}\right)

y_{1}(x)=x^{-4} \sum_{n=0}^{\infty} a_{n} x^{n}, y_{2}(x)=y_{1}(x) \ln x+x^{-4} \sum_{n=0}^{\infty} b_{n} x^{n}

\left.y_{1}(x)=x^{4} \sum_{n=0}^{\infty} a_{n} x^{n}, y_{2}(x)=y_{1} x\right) \ln x+x^{4} \sum_{n=0}^{\infty} b_{n} x^{n}

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Deck 5: Series Solutions of Second-Order Linear Equations

What is the radius of convergence of the power series $What is the radius of convergence of the power series ? A) 0 B) 1 C) 8 D) \infty$ ?

A) 0
B) 1
C) 8
D)

\infty

What is the radius of convergence of the power series $What is the radius of convergence of the power series ? A) B) 4 C) 2 D) 6 E) \infty$ ?

A) $What is the radius of convergence of the power series ? A) B) 4 C) 2 D) 6 E) \infty$
B) 4
C) 2
D) 6
E)

\infty

What is the radius of convergence of the power series ?

A) 0
B)

C) 1
D) 6
E) 7

What is the radius of convergence of the power series $What is the radius of convergence of the power series ? A) 5 B) 6 C) 36 D) \infty$ ?

A) 5
B) 6
C) 36
D)

\infty

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What is the Taylor series expansion for f(x) = sin(6x) about x = 0?

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What is the Taylor expansion for f(x) = cos(7x) about x = 0?

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What is the Taylor series expansion for f(x) = about x = 0?

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Which of these power series is equivalent to ? Select all that apply.

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Which of these power series is equivalent to + 7 ?

C) ?

D) ?

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Which of these are singular points for the differential equation

Select all that apply.

A) -2
B) 6
C) -3
D) 2
E) 0

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Which of these are ordinary points for the differential equation
(x + 5) + ( - 49) + 2xy = 0?
Select all that apply.

A) -5
B) -7
C) 7
D) 0
E) 12

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Which of these are singular points for the differential equation

Select all that apply.

A) -5
B) -7
C) 5
D) 6
E) 7
F) 8

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Consider the second-order differential equation $Consider the second-order differential equation + 64y = 0. Assume a solution of this equation can be represented as a power series What is the recurrence relation for the coefficientsCn ? Assume that C0 and C1 are known. A) c_{n+2}+64 c_{n}=0, n=0,1,2, \ldots B) c_{n+1}+64 c_{n}=0, n=0,1,2, \ldots C) (n+1)(n+2) c_{n+2}+64 c_{n}=0, n=0,1,2, \ldots D) n(n+1) c_{n+1}+64 c_{n}=0, n=0,1,2, \ldots$ + 64y = 0.
Assume a solution of this equation can be represented as a power series $Consider the second-order differential equation + 64y = 0. Assume a solution of this equation can be represented as a power series What is the recurrence relation for the coefficientsCn ? Assume that C0 and C1 are known. A) c_{n+2}+64 c_{n}=0, n=0,1,2, \ldots B) c_{n+1}+64 c_{n}=0, n=0,1,2, \ldots C) (n+1)(n+2) c_{n+2}+64 c_{n}=0, n=0,1,2, \ldots D) n(n+1) c_{n+1}+64 c_{n}=0, n=0,1,2, \ldots$
What is the recurrence relation for the coefficientsC_n ? Assume that C₀ and C₁ are known.

c_{n+2}+64 c_{n}=0, n=0,1,2, \ldots

c_{n+1}+64 c_{n}=0, n=0,1,2, \ldots

(n+1)(n+2) c_{n+2}+64 c_{n}=0, n=0,1,2, \ldots

n(n+1) c_{n+1}+64 c_{n}=0, n=0,1,2, \ldots

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Consider the second-order differential equation

+ 49y = 0.
Assume a solution of this equation can be represented as a power series

Write down the explicit formulas for the coefficients C_n

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Consider the second-order differential equation

+ 100y = 0.
Assume a solution of this equation can be represented as a power series

Assume the solution of the given differential equation is written as

Identify elementary functions for y₁ (x) and y₂ (x).
y₁ (x) = ________
y₂ (x) = ________

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Consider the second-order differential equation $Consider the second-order differential equation - 4x + y = 0. Assume a solution of this equation can be represented as a power series What is the recurrence relation for the coefficients Cn? Assume that C0 and C1 are known A) c_{n+2}-(4 n-1) c_{n}=0, n=0,1,2, \ldots B) (n+1)(n+2) c_{n+2}-(4 n-1) c_{n}=0, n=0,1,2, \ldots C) (n+1) c_{n+1}-(4 n-1) c_{n}=0, n=0,1,2, \ldots D) c_{n+1}-(4 n-1) c_{n}=0, n=0,1,2, \ldots$ - 4x $Consider the second-order differential equation - 4x + y = 0. Assume a solution of this equation can be represented as a power series What is the recurrence relation for the coefficients Cn? Assume that C0 and C1 are known A) c_{n+2}-(4 n-1) c_{n}=0, n=0,1,2, \ldots B) (n+1)(n+2) c_{n+2}-(4 n-1) c_{n}=0, n=0,1,2, \ldots C) (n+1) c_{n+1}-(4 n-1) c_{n}=0, n=0,1,2, \ldots D) c_{n+1}-(4 n-1) c_{n}=0, n=0,1,2, \ldots$ + y = 0.
Assume a solution of this equation can be represented as a power series $Consider the second-order differential equation - 4x + y = 0. Assume a solution of this equation can be represented as a power series What is the recurrence relation for the coefficients Cn? Assume that C0 and C1 are known A) c_{n+2}-(4 n-1) c_{n}=0, n=0,1,2, \ldots B) (n+1)(n+2) c_{n+2}-(4 n-1) c_{n}=0, n=0,1,2, \ldots C) (n+1) c_{n+1}-(4 n-1) c_{n}=0, n=0,1,2, \ldots D) c_{n+1}-(4 n-1) c_{n}=0, n=0,1,2, \ldots$
What is the recurrence relation for the coefficients C_n? Assume that C₀ and C₁ are known

c_{n+2}-(4 n-1) c_{n}=0, n=0,1,2, \ldots

(n+1)(n+2) c_{n+2}-(4 n-1) c_{n}=0, n=0,1,2, \ldots

(n+1) c_{n+1}-(4 n-1) c_{n}=0, n=0,1,2, \ldots

c_{n+1}-(4 n-1) c_{n}=0, n=0,1,2, \ldots

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Consider the second-order differential equation

Assume a solution of this equation can be represented as a power series

Write down the following explicit formulas for the coefficients C_n:
C_2n= ________, n = 0, 1, 2, ...
C_2n+1= ________, n = 0, 1, 2, ...

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Consider the first-order differential equation $Consider the first-order differential equation - 5y = 0. Assume a solution of this equation can be represented as a power series What is the recurrence relation for the coefficients Cn? Assume that C0 is known A) c_{n+1}-5 c_{n}=0, n=0,1,2, \ldots B) (n+1)(n+2) c_{n+1}-5 c_{n}=0, n=0,1,2, \ldots C) (n+1) c_{n+1}+5 c_{n}=0, n=0,1,2, \ldots D) (n+1) c_{n+1}-5 c_{n}=0, n=0,1,2, \ldots$ - 5y = 0.
Assume a solution of this equation can be represented as a power series $Consider the first-order differential equation - 5y = 0. Assume a solution of this equation can be represented as a power series What is the recurrence relation for the coefficients Cn? Assume that C0 is known A) c_{n+1}-5 c_{n}=0, n=0,1,2, \ldots B) (n+1)(n+2) c_{n+1}-5 c_{n}=0, n=0,1,2, \ldots C) (n+1) c_{n+1}+5 c_{n}=0, n=0,1,2, \ldots D) (n+1) c_{n+1}-5 c_{n}=0, n=0,1,2, \ldots$
What is the recurrence relation for the coefficients C_n? Assume that C₀ is known

c_{n+1}-5 c_{n}=0, n=0,1,2, \ldots

(n+1)(n+2) c_{n+1}-5 c_{n}=0, n=0,1,2, \ldots

(n+1) c_{n+1}+5 c_{n}=0, n=0,1,2, \ldots

(n+1) c_{n+1}-5 c_{n}=0, n=0,1,2, \ldots

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Consider the first-order differential equation

- 7y = 0.
Assume a solution of this equation can be represented as a power series

Write down the following explicit formula for the coefficients C_n

= , n = 0, 1, 2, ...

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Consider the first-order differential equation $Consider the first-order differential equation - 7y = 0. Assume a solution of this equation can be represented as a power series Which of these elementary functions is equal to the power series representation of the solution? A) y=2^{c_{0}} e^{x} B) y=c_{0} e^{2 x} C) y=c_{0} e^{x} D) y=c_{0} e^{\frac{x}{2}} E) y=\frac{c_{0}}{2} e^{x}$ - 7y = 0.
Assume a solution of this equation can be represented as a power series $Consider the first-order differential equation - 7y = 0. Assume a solution of this equation can be represented as a power series Which of these elementary functions is equal to the power series representation of the solution? A) y=2^{c_{0}} e^{x} B) y=c_{0} e^{2 x} C) y=c_{0} e^{x} D) y=c_{0} e^{\frac{x}{2}} E) y=\frac{c_{0}}{2} e^{x}$
Which of these elementary functions is equal to the power series representation of the solution?

y=2^{c_{0}} e^{x}

y=c_{0} e^{2 x}

y=c_{0} e^{x}

y=c_{0} e^{\frac{x}{2}}

y=\frac{c_{0}}{2} e^{x}

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Consider the first-order differential equation $Consider the first-order differential equation Assume a solution of this equation can be represented as a power series . Assume that C0 is known. Which of these power series equals y(x)? A) \sum_{n=0}^{\infty} \frac{17 c_{0}}{3(n !)^{2}} x^{3 n} B) \sum_{n=0}^{\infty} \frac{c_{0} 17^{n}}{n ! 3} x^{3 n} C) \sum_{n=0}^{\infty} \frac{17 c_{0}}{3^{n} n !} x^{3 n} D) \sum_{n=0}^{\infty} \frac{17 c_{0}}{3^{n}(n !)^{2}} x^{3 n}$
Assume a solution of this equation can be represented as a power series $Consider the first-order differential equation Assume a solution of this equation can be represented as a power series . Assume that C0 is known. Which of these power series equals y(x)? A) \sum_{n=0}^{\infty} \frac{17 c_{0}}{3(n !)^{2}} x^{3 n} B) \sum_{n=0}^{\infty} \frac{c_{0} 17^{n}}{n ! 3} x^{3 n} C) \sum_{n=0}^{\infty} \frac{17 c_{0}}{3^{n} n !} x^{3 n} D) \sum_{n=0}^{\infty} \frac{17 c_{0}}{3^{n}(n !)^{2}} x^{3 n}$ .
Assume that C₀ is known.
Which of these power series equals y(x)?

\sum_{n=0}^{\infty} \frac{17 c_{0}}{3(n !)^{2}} x^{3 n}

\sum_{n=0}^{\infty} \frac{c_{0} 17^{n}}{n ! 3} x^{3 n}

\sum_{n=0}^{\infty} \frac{17 c_{0}}{3^{n} n !} x^{3 n}

\sum_{n=0}^{\infty} \frac{17 c_{0}}{3^{n}(n !)^{2}} x^{3 n}

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Consider the first-order differential equation

Assume a solution of this equation can be represented as a power series

Assume that C₀ is known.
Identify an elementary function equal to y(x).

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Consider the first-order differential equation

.
Assume a solution of this equation can be represented as a power series

.
Write down the following explicit formulas for the coefficients C_n

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Consider this initial value problem: $Consider this initial value problem: . Assume a solution of this equation can be represented as a power series . Express the solution y(x) as an elementary function. A) y(x)=e^{\frac{(9 x)^{2}}{2}} B) y(x)=e^{\frac{9}{2} x^{2}} C) y(x)=9 e^{\frac{x^{2}}{2}} D) y(x)=\frac{9}{2} e^{x^{2}}$ .
Assume a solution of this equation can be represented as a power series $Consider this initial value problem: . Assume a solution of this equation can be represented as a power series . Express the solution y(x) as an elementary function. A) y(x)=e^{\frac{(9 x)^{2}}{2}} B) y(x)=e^{\frac{9}{2} x^{2}} C) y(x)=9 e^{\frac{x^{2}}{2}} D) y(x)=\frac{9}{2} e^{x^{2}}$ .
Express the solution y(x) as an elementary function.

y(x)=e^{\frac{(9 x)^{2}}{2}}

y(x)=e^{\frac{9}{2} x^{2}}

y(x)=9 e^{\frac{x^{2}}{2}}

y(x)=\frac{9}{2} e^{x^{2}}

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Consider the first-order differential equation $Consider the first-order differential equation . - 7xy = 0. Assume a solution of this equation can be represented as a power series . What is the recurrence relation for the coefficients Cn ? Assume that C0 is known. A) c_{1}=0, n c_{n+1}=7 c_{n-1}, n=1,2, \ldots B) c_{0}=0,(n+1) c_{n}=7 c_{n-1}, n=1,2, \ldots C) c_{0}=0,(n+1) c_{n+1}=7 c_{n-1}, n=1,2, \ldots D) c_{0}=0,(n+1) c_{n+1}=7 c_{n}, n=0,1,2, \ldots E) c_{1}=0,(n+1) c_{n+1}=7 c_{n-1}, n=1,2, \ldots$ . - 7xy = 0.
Assume a solution of this equation can be represented as a power series $Consider the first-order differential equation . - 7xy = 0. Assume a solution of this equation can be represented as a power series . What is the recurrence relation for the coefficients Cn ? Assume that C0 is known. A) c_{1}=0, n c_{n+1}=7 c_{n-1}, n=1,2, \ldots B) c_{0}=0,(n+1) c_{n}=7 c_{n-1}, n=1,2, \ldots C) c_{0}=0,(n+1) c_{n+1}=7 c_{n-1}, n=1,2, \ldots D) c_{0}=0,(n+1) c_{n+1}=7 c_{n}, n=0,1,2, \ldots E) c_{1}=0,(n+1) c_{n+1}=7 c_{n-1}, n=1,2, \ldots$ .
What is the recurrence relation for the coefficients C_n ? Assume that C₀ is known.

c_{1}=0, n c_{n+1}=7 c_{n-1}, n=1,2, \ldots

c_{0}=0,(n+1) c_{n}=7 c_{n-1}, n=1,2, \ldots

c_{0}=0,(n+1) c_{n+1}=7 c_{n-1}, n=1,2, \ldots

c_{0}=0,(n+1) c_{n+1}=7 c_{n}, n=0,1,2, \ldots

c_{1}=0,(n+1) c_{n+1}=7 c_{n-1}, n=1,2, \ldots

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Consider the first-order differential equation $Consider the first-order differential equation - 10xy = 0. Assume a solution of this equation can be represented as a power series Express the solution y(x) as an elementary function. A) y(x)=c_{0} e^{\frac{10}{2} x^{2}} B) y(x)=c_{0} e^{(10 x)^{2}} C) y(x)=c_{1} e^{10 x} D) y(x)=c_{1} e^{10 x^{2}} E) y(x)=c_{1} e^{(10 x)^{2}}$ - 10xy = 0.
Assume a solution of this equation can be represented as a power series $Consider the first-order differential equation - 10xy = 0. Assume a solution of this equation can be represented as a power series Express the solution y(x) as an elementary function. A) y(x)=c_{0} e^{\frac{10}{2} x^{2}} B) y(x)=c_{0} e^{(10 x)^{2}} C) y(x)=c_{1} e^{10 x} D) y(x)=c_{1} e^{10 x^{2}} E) y(x)=c_{1} e^{(10 x)^{2}}$
Express the solution y(x) as an elementary function.

y(x)=c_{0} e^{\frac{10}{2} x^{2}}

y(x)=c_{0} e^{(10 x)^{2}}

y(x)=c_{1} e^{10 x}

y(x)=c_{1} e^{10 x^{2}}

y(x)=c_{1} e^{(10 x)^{2}}

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Consider the second-order differential equation

- 1 y = 0.
Assume a solution of this equation can be represented as a power series

Assume that C₀ and C₁ are known. Write down the following explicit formulas for the coefficients C_n

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Consider the second-order differential equation ‪

- 19x² y = 0.
Assume a solution of this equation can be represented as a power series

Write down the first four nonzero terms of the power series solution.
y(x) ≈ ________

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Consider this initial-value problem:

.
Assume a solution of this equation can be represented as a power series

.
Write down the values of these coefficients:
C₀ = ________,
C₁ = ________,
C₂ = ________,
C₃ = ________,
C₄ = ________,
C₅ = ________,
C₆ = ________

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Consider this initial-value problem:

.
Assume a solution of this equation can be represented as a power series

.
Write down the first four terms of the power series solution.

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Consider the second-order differential equation

.
Assume the solution can be expressed as a power series

. Assume C₀ = 0. Find C₁

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What is the greatest lower bound for the radius of convergence of a series solution for the second-order differential equation (x + 8)

- 7x

+ 7y = 0 about the point

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What is the greatest lower bound for the radius of convergence of a series solution for the second-order differential equation (x - 2)(x + 4)

+7(X +16)

- 8xy = 0 about the point ?

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What is a lower bound for the radius of convergence of a series solution for the second-order differential equation (x - 2)(x + 4)

+ 8(x + 7)

- 7xy = 0 about the point

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What is a lower bound for the radius of convergence of a series solution for the second-order differential equation (x - 6)(x + 12)

+ 6(x + 14)

- 2xy = 0 about the point X₀ = 11?

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A) 0
B) 1
C) $What is the radius of convergence of a series solution for the second-order differential equation . A) 0 B) 1 C) . D) \infty$ .
D)

\infty

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What is a lower bound for the radius of convergence of a series solution for the second-order differential equation

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\sqrt{15}

\frac{1}{4}

\frac{\sqrt{15}}{4}

\frac{1}{2}

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\left\{x^{-3}, x^{3}\right\}

\left\{x^{3}, x^{6}\right\}

\left\{x^{3}, x^{3} \ln x\right\}

\left\{x^{-3}, x^{-3} \ln x\right\}

\left\{x^{3} \cos (\ln x), x^{3} \sin (\ln x)\right\}

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Which of the following pairs forms a fundamental set of solutions of the Cauchy Euler differential equation $Which of the following pairs forms a fundamental set of solutions of the Cauchy Euler differential equation . A) \left\{x^{-5}, x^{-5} \cos (\ln x)\right\} B) \left\{x^{5}, x^{-5}\right\} C) \left\{x^{5}, x^{5} \ln x\right\} D) \left\{x^{-5}, x^{-5} \ln x\right\} E) \left\{x^{5}, x^{5} \cos (\ln x)\right\}$ .

\left\{x^{-5}, x^{-5} \cos (\ln x)\right\}

\left\{x^{5}, x^{-5}\right\}

\left\{x^{5}, x^{5} \ln x\right\}

\left\{x^{-5}, x^{-5} \ln x\right\}

\left\{x^{5}, x^{5} \cos (\ln x)\right\}

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Which of the following pairs forms a fundamental set of solutions of the Cauchy Euler differential equation $Which of the following pairs forms a fundamental set of solutions of the Cauchy Euler differential equation . A) \{\cos (6 \ln x), \sin (6 \ln x)\} B) \left\{x^{6} \cos (\ln x), x^{6} \sin (\ln x)\right\} C) \{\ln (\cos (6 x)), \ln (\sin (6 x))\} D) \left\{x^{-6}, x^{6}\right\} E) \{\cos (\ln (6 x)), \sin (\ln (6 x))\}$ .

\{\cos (6 \ln x), \sin (6 \ln x)\}

\left\{x^{6} \cos (\ln x), x^{6} \sin (\ln x)\right\}

\{\ln (\cos (6 x)), \ln (\sin (6 x))\}

\left\{x^{-6}, x^{6}\right\}

\{\cos (\ln (6 x)), \sin (\ln (6 x))\}

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y=C_{1} x^{-\frac{1}{2}}+C_{2} x^{\frac{1}{2}}

y=C_{1} x^{\frac{1}{2}}+C_{2} x^{\frac{1}{2}} \ln x

y=C_{1} x^{-\frac{1}{2}}+C_{2} x^{-\frac{1}{2}} \ln x

y=x^{-\frac{1}{2}}\left(C_{1} \sin \frac{1}{2} \ln x+C_{2} \cos \frac{1}{2} \ln x\right)

y=x^{-\frac{1}{2}}\left(C_{1} \sin \ln \frac{1}{2} x+C_{2} \cos \ln \frac{1}{2} x\right)

y=x^{\frac{1}{2}}\left(C_{1} \sin -\frac{1}{2} \ln x+C_{2} \cos -\frac{1}{2} \ln x\right)

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y=C_{1} x^{-\frac{8}{5}}+C_{2} x^{-\frac{8}{3}}

y=C_{1} x^{\frac{8}{5}}+C_{2} x^{\frac{8}{3}}

y=C_{1} x^{\frac{5}{8}}+C_{2} x^{\frac{5}{8}} \ln x

y=C_{1} x^{\frac{8}{3}}+C_{2} x^{\frac{8}{3}} \ln x

y=C_{1} x^{\frac{8}{5}}+C_{2} x^{-\frac{8}{3}}

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y=C_{1} x^{-2}+C_{2} x^{-7}

y=C_{1} x^{2}+C_{2} x^{-7}

y=C_{1} x^{-2}+C_{2} x^{7}

y=C_{1} x^{2}+C_{2} x^{7}

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y=\frac{25}{9} x^{6}+\frac{25}{9} x^{-3}

y=\frac{25}{9} x^{-6}+\frac{25}{9} x^{3}

y=-\frac{25}{3} x^{6}-\frac{40}{3} x^{-3}

y=-\frac{25}{3} x^{-6}-\frac{40}{3} x^{3}

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Solve this initial value problem:

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y=C_{1}(x-3)^{5}+C_{2}(x-3)^{5} \ln x

y=C_{1}(x-3)^{-5}+C_{2}(x-3)^{5}

y=C_{1}(x-3)^{-5}+C_{2}(x-3)^{-5} \ln x

y=C_{1}(x-3)^{5}+C_{2}(x-3)^{10}

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y=(x+1)^{-7}\left(C_{1}+C_{2} \ln x\right)

y=C_{1}(x+1)^{-7}+C_{2}(x+1)^{7}

y=(x+1)^{-7}\left(C_{1} \sin (\ln x)+C_{2} \cos (\ln x)\right)

y=(x+1)^{7}\left(C_{1}+C_{2} \ln x\right)

y=(x+1)^{7}\left(C_{1} \ln (\sin x)+C_{2} \ln (\cos x)\right)

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Consider the Bessel equation of order .
Which of these statements is true?

A) x = 7 is a regular singular point.
B) x = 0 is a regular singular point.
C) x = 0 is an irregular singular point.
D) There are no singular points.

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Consider the Legendre equation: .
Which of these statements is true?

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Consider the second-order differential equation .
Which of these statements is true?

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Consider the second-order differential equation: .
Which of these statements is true?

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Consider the second-order differential equation .
Which of these statements is true?

A) x = 0 is a regular singular point.
B) x = -8 is a regular singular point.
C) x = -8 is an irregular singular point.
D) There are no singular points.

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x = 0 is a regular singular point for the second-order differential equation

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Consider the second-order differential equation .
Which of these statements is true?

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A) The functions

x^{2} \cdot \frac{7 x(x+1)}{5 x^{2}}

and

x \cdot\left(-\frac{7}{5 x^{2}}\right)

both have convergent Taylor series expansions about 0 .
B) The functions

x \cdot \frac{7 x(x+1)}{5 x^{2}}

and

x^{2} \cdot\left(-\frac{7}{5 x^{2}}\right)

both have convergent Taylor series expansions about 0 .
C)

\lim _{x \rightarrow 0} x \cdot\left(-\frac{7}{5 x^{2}}\right)=\infty

\lim _{x \rightarrow 0} x \cdot\left(-\frac{7}{5 x^{2}}\right) \neq 0

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Consider the second-order differential equation: .
Which of these is the indicial equation?

A) (3r - 1)(r + 5) = 0
B) (3r + 1)(r - 5) = 0
C) (3r + 5)(r - 1) = 0
D) (3r - 5)(r + 1) = 0

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Consider the second-order differential equation: $Consider the second-order differential equation: . Which of these is the recurrence relation for the coefficients? A) a_{n}=\frac{-2(n+r-1) a_{n-1}}{(2(n+r)+5)(n+r+1)}, n \geq 1 B) a_{n}=\frac{2(n+r-1) a_{n-1}}{(2(n+r)-5)(n+r+1)}, n \geq 1 C) a_{n}=\frac{-2(n+r-1) a_{n-1}}{(2(n+r)-1)(n+r+5)}, n \geq 1 D) a_{n}=\frac{2(n+r-1) a_{n-1}}{(2(n+r)+1)(n+r-5)}, n \geq 1$ .
Which of these is the recurrence relation for the coefficients?

a_{n}=\frac{-2(n+r-1) a_{n-1}}{(2(n+r)+5)(n+r+1)}, n \geq 1

a_{n}=\frac{2(n+r-1) a_{n-1}}{(2(n+r)-5)(n+r+1)}, n \geq 1

a_{n}=\frac{-2(n+r-1) a_{n-1}}{(2(n+r)-1)(n+r+5)}, n \geq 1

a_{n}=\frac{2(n+r-1) a_{n-1}}{(2(n+r)+1)(n+r-5)}, n \geq 1

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Consider the second-order differential equation:

.
Write out the first three terms of the solution corresponding to the positive root of the indicial equation.
Y₁ (x) ≈ ________

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Consider the second-order differential equation:

.
Write out the first three terms of the solution corresponding to the nonpositive root of the indicial equation.
Y₂ (x) ≈ ________

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Consider the second-order differential equation:

.
The general solution of the differential equation is

.
are arbitrary real constants.

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Consider the Bessel equation of order $Consider the Bessel equation of order . Suppose the method of Frobenius is used to determine a power series solution of the form . Of this differential equation. Assume a0 \neq 0. Which of these is the indicial equation? A) r2 - 36 = 0 B) r2- 6 = 0 C) r2+ 6 = 0 D) r2+ 36 = 0$ .
Suppose the method of Frobenius is used to determine a power series solution of the form $Consider the Bessel equation of order . Suppose the method of Frobenius is used to determine a power series solution of the form . Of this differential equation. Assume a0 \neq 0. Which of these is the indicial equation? A) r2 - 36 = 0 B) r2- 6 = 0 C) r2+ 6 = 0 D) r2+ 36 = 0$ .
Of this differential equation. Assume a₀ $\neq$ 0.
Which of these is the indicial equation?

A) r² - 36 = 0
B) r²- 6 = 0
C) r²+ 6 = 0
D) r²+ 36 = 0

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Consider the Bessel equation of order $Consider the Bessel equation of order . Suppose the method of Frobenius is used to determine a power series solution of the form . Of this differential equation. Assume a0 \neq 0. Which of these is the recurrence relation for the coefficients? A) a_{1}=0, a_{n+2}=\frac{-a_{n}}{(r+n-2)^{2}+16}, n \geq 0 B) a_{1}=0, a_{n+2}=\frac{-a_{n}}{(r+n+2)^{2}-16}, n \geq 0 C) a_{1}=1, a_{n+2}=\frac{-a_{n}}{(r+n-2)^{2}+16}, n \geq 0 D) a_{1}=1, a_{n+2}=\frac{-a_{n}}{(r+n+2)^{2}-16}, n \geq 0$ .
Suppose the method of Frobenius is used to determine a power series solution of the form $Consider the Bessel equation of order . Suppose the method of Frobenius is used to determine a power series solution of the form . Of this differential equation. Assume a0 \neq 0. Which of these is the recurrence relation for the coefficients? A) a_{1}=0, a_{n+2}=\frac{-a_{n}}{(r+n-2)^{2}+16}, n \geq 0 B) a_{1}=0, a_{n+2}=\frac{-a_{n}}{(r+n+2)^{2}-16}, n \geq 0 C) a_{1}=1, a_{n+2}=\frac{-a_{n}}{(r+n-2)^{2}+16}, n \geq 0 D) a_{1}=1, a_{n+2}=\frac{-a_{n}}{(r+n+2)^{2}-16}, n \geq 0$ .
Of this differential equation. Assume a₀ $\neq$ 0.
Which of these is the recurrence relation for the coefficients?

a_{1}=0, a_{n+2}=\frac{-a_{n}}{(r+n-2)^{2}+16}, n \geq 0

a_{1}=0, a_{n+2}=\frac{-a_{n}}{(r+n+2)^{2}-16}, n \geq 0

a_{1}=1, a_{n+2}=\frac{-a_{n}}{(r+n-2)^{2}+16}, n \geq 0

a_{1}=1, a_{n+2}=\frac{-a_{n}}{(r+n+2)^{2}-16}, n \geq 0

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Consider the Bessel equation of order $Consider the Bessel equation of order . Suppose the method of Frobenius is used to determine a power series solution of the form . Of this differential equation. Assume a0 \neq 0. Which of these is the explicit formula for the coefficients corresponding to the positive root of the indicial equation? A) a_{2 n}=0 and a_{2 n+1}=(-1)^{n} \cdot \frac{a_{0} \cdot 4 !}{2^{n+1}(n+1) !(n+4) !}, n \geq 1 B) a_{2 n}=0 and a_{2 n+1}=(-1)^{n} \cdot \frac{a_{0} \cdot 4 !}{2^{2 n} n !(n+4) !}, n \geq 1 C) a_{2 n+1}=0 and a_{2 n}=(-1)^{n-1} \cdot \frac{a_{0} \cdot 4 !}{2^{n} n !(n+4) !}, n \geq 1 D) a_{2 n+1}=0 and a_{2 n}=(-1)^{n} \cdot \frac{a_{0} \cdot 4 !}{2^{2 n} n !(n+4) !}, n \geq 1$ .
Suppose the method of Frobenius is used to determine a power series solution of the form $Consider the Bessel equation of order . Suppose the method of Frobenius is used to determine a power series solution of the form . Of this differential equation. Assume a0 \neq 0. Which of these is the explicit formula for the coefficients corresponding to the positive root of the indicial equation? A) a_{2 n}=0 and a_{2 n+1}=(-1)^{n} \cdot \frac{a_{0} \cdot 4 !}{2^{n+1}(n+1) !(n+4) !}, n \geq 1 B) a_{2 n}=0 and a_{2 n+1}=(-1)^{n} \cdot \frac{a_{0} \cdot 4 !}{2^{2 n} n !(n+4) !}, n \geq 1 C) a_{2 n+1}=0 and a_{2 n}=(-1)^{n-1} \cdot \frac{a_{0} \cdot 4 !}{2^{n} n !(n+4) !}, n \geq 1 D) a_{2 n+1}=0 and a_{2 n}=(-1)^{n} \cdot \frac{a_{0} \cdot 4 !}{2^{2 n} n !(n+4) !}, n \geq 1$ .
Of this differential equation. Assume a₀ $\neq$ 0.
Which of these is the explicit formula for the coefficients corresponding to the positive root of the indicial equation?

a_{2 n}=0

and

a_{2 n+1}=(-1)^{n} \cdot \frac{a_{0} \cdot 4 !}{2^{n+1}(n+1) !(n+4) !}, n \geq 1

a_{2 n}=0

and

a_{2 n+1}=(-1)^{n} \cdot \frac{a_{0} \cdot 4 !}{2^{2 n} n !(n+4) !}, n \geq 1

a_{2 n+1}=0

and

a_{2 n}=(-1)^{n-1} \cdot \frac{a_{0} \cdot 4 !}{2^{n} n !(n+4) !}, n \geq 1

a_{2 n+1}=0

and

a_{2 n}=(-1)^{n} \cdot \frac{a_{0} \cdot 4 !}{2^{2 n} n !(n+4) !}, n \geq 1

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Consider the Bessel equation of order

.
Suppose the method of Frobenius is used to determine a power series solution of the form

.
of this differential equation. Assume a₀ ≠ 0.
Write the power series solution corresponding to the positive root of the indicial equation.
Y₁ (x) = ________

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Consider the second-order differential equation $Consider the second-order differential equation . Write the differential equation in the form . a regular singular point for this equation? A) x^{2} p(x) and x q(x) both have convergent Taylor expansions about 0 . B) \lim _{x \rightarrow 0} x^{2} p(x)=0 and \lim _{x \rightarrow 0} x q(x)=\infty C) \lim _{x \rightarrow 0} x p(x) is finite and \lim _{x \rightarrow 0} x^{2} \gamma(x)=\infty D) \lim _{x \rightarrow 0} x p(x) is finite and x^{2} \gamma(x) has a convergent Taylor expansion about 0 .$ .
Write the differential equation in the form $Consider the second-order differential equation . Write the differential equation in the form . a regular singular point for this equation? A) x^{2} p(x) and x q(x) both have convergent Taylor expansions about 0 . B) \lim _{x \rightarrow 0} x^{2} p(x)=0 and \lim _{x \rightarrow 0} x q(x)=\infty C) \lim _{x \rightarrow 0} x p(x) is finite and \lim _{x \rightarrow 0} x^{2} \gamma(x)=\infty D) \lim _{x \rightarrow 0} x p(x) is finite and x^{2} \gamma(x) has a convergent Taylor expansion about 0 .$ . a regular singular point for this equation?

x^{2} p(x)

and

x q(x)

both have convergent Taylor expansions about 0 .
B)

\lim _{x \rightarrow 0} x^{2} p(x)=0

and

\lim _{x \rightarrow 0} x q(x)=\infty

\lim _{x \rightarrow 0} x p(x)

is finite and

\lim _{x \rightarrow 0} x^{2} \gamma(x)=\infty

\lim _{x \rightarrow 0} x p(x)

is finite and

x^{2} \gamma(x)

has a convergent Taylor expansion about 0 .

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Consider the second-order differential equation $Consider the second-order differential equation . Suppose the method of Frobineius is used to determine a power series solution of the form . Of this differential equation. Assume a0 \neq 0. Which of these is the indicial equation? A) r2+ 7r = 0 B) + 8r = 0 C) - 8r = 0 D) - 7r = 0$ .
Suppose the method of Frobineius is used to determine a power series solution of the form $Consider the second-order differential equation . Suppose the method of Frobineius is used to determine a power series solution of the form . Of this differential equation. Assume a0 \neq 0. Which of these is the indicial equation? A) r2+ 7r = 0 B) + 8r = 0 C) - 8r = 0 D) - 7r = 0$ .
Of this differential equation. Assume a₀ $\neq$ 0. Which of these is the indicial equation?

A) r²+ 7r = 0
B) $Consider the second-order differential equation . Suppose the method of Frobineius is used to determine a power series solution of the form . Of this differential equation. Assume a0 \neq 0. Which of these is the indicial equation? A) r2+ 7r = 0 B) + 8r = 0 C) - 8r = 0 D) - 7r = 0$ + 8r = 0
C) $Consider the second-order differential equation . Suppose the method of Frobineius is used to determine a power series solution of the form . Of this differential equation. Assume a0 \neq 0. Which of these is the indicial equation? A) r2+ 7r = 0 B) + 8r = 0 C) - 8r = 0 D) - 7r = 0$ - 8r = 0
D) $Consider the second-order differential equation . Suppose the method of Frobineius is used to determine a power series solution of the form . Of this differential equation. Assume a0 \neq 0. Which of these is the indicial equation? A) r2+ 7r = 0 B) + 8r = 0 C) - 8r = 0 D) - 7r = 0$ - 7r = 0

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Consider the second-order differential equation $Consider the second-order differential equation . Suppose the method of Frobenius is used to determine a power series solution of the form . Of this differential equation. Assume a0 \neq 0. Which of these is the indicial equation? A) r2 + r = 0 B) r2 - r = 0 C) r2 + r - 2 = 0 D) r2 - r - 2 = 0$ .
Suppose the method of Frobenius is used to determine a power series solution of the form $Consider the second-order differential equation . Suppose the method of Frobenius is used to determine a power series solution of the form . Of this differential equation. Assume a0 \neq 0. Which of these is the indicial equation? A) r2 + r = 0 B) r2 - r = 0 C) r2 + r - 2 = 0 D) r2 - r - 2 = 0$ .
Of this differential equation. Assume a₀ $\neq$ 0.
Which of these is the indicial equation?

A) r² + r = 0
B) r² - r = 0
C) r² + r - 2 = 0
D) r² - r - 2 = 0

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Consider the second-order differential equation

.
Suppose the method of Frobenius is used to determine a power series solution of the form

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a_{1}=0, a_{n}=-\frac{64 \cdot a_{n-2}}{2^{n}}, n \geq 2

a_{1}=1, a_{n}=\frac{64 \cdot a_{n-2}}{2^{n}}, n \geq 2

a_{1}=1, a_{n}=\frac{64 \cdot a_{n-2}}{n^{2}}, n \geq 2

a_{1}=0, a_{n}=-\frac{64 \cdot a_{n-2}}{n^{2}}, n \geq 2

a_{1}=0, a_{n}=-\frac{64 \cdot a_{n-2}}{n}, n \geq 2

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a_{2 n}=\frac{(-1)^{n} 2^{3 n}}{n !} a_{0, n} \geq 1

a_{2 n}=\frac{(-1)^{n} 2^{5 n}}{n !} a_{0}, n \geq 1

a_{2 n}=\frac{(-1)^{n} 2^{3 n}}{(n !)^{2}} a_{0}, n \geq 1

a_{2 n}=\frac{(-1)^{n} 2^{5 n}}{(n !)^{2}} a_{0}, n \geq 1

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Consider the second-order differential equation $Consider the second-order differential equation . Suppose the method of Frobenius is used to determine a power series solution of this equation. The indicial equation has r = 0 as a double root. So, one of the solutions can be represented as the power series . Assume a0 \neq 0. Assuming that a0 = 1, one solution of the given differential equation is . Assume x > 0. Which of these is a form of a second solution of the given differential equation, linearly independent to (x)? A) y_{2}(x)=y_{1}(x) \ln x+\sum_{n=1}^{\infty} a^{*}{ }_{n} x^{n} B) y_{2}(x)=y_{1}^{\prime}(x) \ln x \mid+\sum_{n=1}^{\infty} a^{*} n^{n} C) y_{2}(x)=\ln x+y_{1}(x) \cdot \sum_{n=1}^{\infty} a^{*}{ }_{n} x^{n} D) y_{2}(x)=|\ln x|+y_{1}(x) \cdot \sum_{n=1}^{\infty} a^{n}{ }_{n} x^{n} E) y_{2}(x)=\ln x\left(y_{1}(x)+\sum_{n=1}^{\infty} a^{n}{ }_{n} x^{n}\right)$ .
Suppose the method of Frobenius is used to determine a power series solution of this equation. The indicial equation has r = 0 as a double root. So, one of the solutions can be represented as the power series $Consider the second-order differential equation . Suppose the method of Frobenius is used to determine a power series solution of this equation. The indicial equation has r = 0 as a double root. So, one of the solutions can be represented as the power series . Assume a0 \neq 0. Assuming that a0 = 1, one solution of the given differential equation is . Assume x > 0. Which of these is a form of a second solution of the given differential equation, linearly independent to (x)? A) y_{2}(x)=y_{1}(x) \ln x+\sum_{n=1}^{\infty} a^{*}{ }_{n} x^{n} B) y_{2}(x)=y_{1}^{\prime}(x) \ln x \mid+\sum_{n=1}^{\infty} a^{*} n^{n} C) y_{2}(x)=\ln x+y_{1}(x) \cdot \sum_{n=1}^{\infty} a^{*}{ }_{n} x^{n} D) y_{2}(x)=|\ln x|+y_{1}(x) \cdot \sum_{n=1}^{\infty} a^{n}{ }_{n} x^{n} E) y_{2}(x)=\ln x\left(y_{1}(x)+\sum_{n=1}^{\infty} a^{n}{ }_{n} x^{n}\right)$ .
Assume a₀ $\neq$ 0.
Assuming that a₀ = 1, one solution of the given differential equation is $Consider the second-order differential equation . Suppose the method of Frobenius is used to determine a power series solution of this equation. The indicial equation has r = 0 as a double root. So, one of the solutions can be represented as the power series . Assume a0 \neq 0. Assuming that a0 = 1, one solution of the given differential equation is . Assume x > 0. Which of these is a form of a second solution of the given differential equation, linearly independent to (x)? A) y_{2}(x)=y_{1}(x) \ln x+\sum_{n=1}^{\infty} a^{*}{ }_{n} x^{n} B) y_{2}(x)=y_{1}^{\prime}(x) \ln x \mid+\sum_{n=1}^{\infty} a^{*} n^{n} C) y_{2}(x)=\ln x+y_{1}(x) \cdot \sum_{n=1}^{\infty} a^{*}{ }_{n} x^{n} D) y_{2}(x)=|\ln x|+y_{1}(x) \cdot \sum_{n=1}^{\infty} a^{n}{ }_{n} x^{n} E) y_{2}(x)=\ln x\left(y_{1}(x)+\sum_{n=1}^{\infty} a^{n}{ }_{n} x^{n}\right)$ .
Assume x > 0. Which of these is a form of a second solution of the given differential equation, linearly independent to (x)?

y_{2}(x)=y_{1}(x) \ln x+\sum_{n=1}^{\infty} a^{*}{ }_{n} x^{n}

y_{2}(x)=y_{1}^{\prime}(x) \ln x \mid+\sum_{n=1}^{\infty} a^{*} n^{n}

y_{2}(x)=\ln x+y_{1}(x) \cdot \sum_{n=1}^{\infty} a^{*}{ }_{n} x^{n}

y_{2}(x)=|\ln x|+y_{1}(x) \cdot \sum_{n=1}^{\infty} a^{n}{ }_{n} x^{n}

y_{2}(x)=\ln x\left(y_{1}(x)+\sum_{n=1}^{\infty} a^{n}{ }_{n} x^{n}\right)

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Consider the second-order differential equation $Consider the second-order differential equation . Suppose the method of Frobenius is used to determine a power series solution of this equation. The indicial equation has r = 0 as a double root. So, one of the solutions can be represented as the power series Assume a0 \neq 0. Assuming that a0 = 1, one solution of the given differential equation is Differentiating as needed, which of these relationships is correct? A) 2 y^{\prime}(x)-a_{1}^{*}-128 a_{2}^{*} x+\sum_{n=3}^{\infty}\left(n^{2} a_{n}^{*}-128 a_{n-2}^{*}\right) x^{n-1}=0 B) 2 y^{\prime}(x)+a_{1}^{*}+128 a_{2}^{*} x+\sum_{n=3}^{\infty}\left(n^{2} a_{n}^{*}+128 a_{n-2}^{*}\right) x^{n-1}=0 C) 2 y^{\prime}(x)+a_{1}^{*}-128 a_{2}^{*} x-\sum_{n=3}^{\infty}\left(n^{2} a_{n}^{*}+128 a_{n-2}^{*}\right) x^{n-1}=0 D) 2 y^{\prime}(x)+a_{1}^{*}+128 a_{2}^{*} x+\sum_{n=3}^{\infty}\left(n^{2} a_{n}^{*}-128 a_{n-2}^{*}\right) x^{n-1}=0$ .
Suppose the method of Frobenius is used to determine a power series solution of this equation. The indicial equation has r = 0 as a double root. So, one of the solutions can be represented as the power series $Consider the second-order differential equation . Suppose the method of Frobenius is used to determine a power series solution of this equation. The indicial equation has r = 0 as a double root. So, one of the solutions can be represented as the power series Assume a0 \neq 0. Assuming that a0 = 1, one solution of the given differential equation is Differentiating as needed, which of these relationships is correct? A) 2 y^{\prime}(x)-a_{1}^{*}-128 a_{2}^{*} x+\sum_{n=3}^{\infty}\left(n^{2} a_{n}^{*}-128 a_{n-2}^{*}\right) x^{n-1}=0 B) 2 y^{\prime}(x)+a_{1}^{*}+128 a_{2}^{*} x+\sum_{n=3}^{\infty}\left(n^{2} a_{n}^{*}+128 a_{n-2}^{*}\right) x^{n-1}=0 C) 2 y^{\prime}(x)+a_{1}^{*}-128 a_{2}^{*} x-\sum_{n=3}^{\infty}\left(n^{2} a_{n}^{*}+128 a_{n-2}^{*}\right) x^{n-1}=0 D) 2 y^{\prime}(x)+a_{1}^{*}+128 a_{2}^{*} x+\sum_{n=3}^{\infty}\left(n^{2} a_{n}^{*}-128 a_{n-2}^{*}\right) x^{n-1}=0$ Assume a₀ $\neq$ 0.
Assuming that a₀ = 1, one solution of the given differential equation is $Consider the second-order differential equation . Suppose the method of Frobenius is used to determine a power series solution of this equation. The indicial equation has r = 0 as a double root. So, one of the solutions can be represented as the power series Assume a0 \neq 0. Assuming that a0 = 1, one solution of the given differential equation is Differentiating as needed, which of these relationships is correct? A) 2 y^{\prime}(x)-a_{1}^{*}-128 a_{2}^{*} x+\sum_{n=3}^{\infty}\left(n^{2} a_{n}^{*}-128 a_{n-2}^{*}\right) x^{n-1}=0 B) 2 y^{\prime}(x)+a_{1}^{*}+128 a_{2}^{*} x+\sum_{n=3}^{\infty}\left(n^{2} a_{n}^{*}+128 a_{n-2}^{*}\right) x^{n-1}=0 C) 2 y^{\prime}(x)+a_{1}^{*}-128 a_{2}^{*} x-\sum_{n=3}^{\infty}\left(n^{2} a_{n}^{*}+128 a_{n-2}^{*}\right) x^{n-1}=0 D) 2 y^{\prime}(x)+a_{1}^{*}+128 a_{2}^{*} x+\sum_{n=3}^{\infty}\left(n^{2} a_{n}^{*}-128 a_{n-2}^{*}\right) x^{n-1}=0$
Differentiating as needed, which of these relationships is correct?

2 y^{\prime}(x)-a_{1}^{*}-128 a_{2}^{*} x+\sum_{n=3}^{\infty}\left(n^{2} a_{n}^{*}-128 a_{n-2}^{*}\right) x^{n-1}=0

2 y^{\prime}(x)+a_{1}^{*}+128 a_{2}^{*} x+\sum_{n=3}^{\infty}\left(n^{2} a_{n}^{*}+128 a_{n-2}^{*}\right) x^{n-1}=0

2 y^{\prime}(x)+a_{1}^{*}-128 a_{2}^{*} x-\sum_{n=3}^{\infty}\left(n^{2} a_{n}^{*}+128 a_{n-2}^{*}\right) x^{n-1}=0

2 y^{\prime}(x)+a_{1}^{*}+128 a_{2}^{*} x+\sum_{n=3}^{\infty}\left(n^{2} a_{n}^{*}-128 a_{n-2}^{*}\right) x^{n-1}=0

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Consider the second-order differential equation

. Assume a₀ ≠ 0.
Assuming that a₀= 1, one solution of the given differential equation is

Assuming that

are known, what is the radius of convergence of the power series of the second solution Y₂ (x)?

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Consider the second-order differential equation $Consider the second-order differential equation . Using the method of Frobenius, which of these is the general solution of this differential equation? Assume are arbitrary real constants. A) y(x)=a_{0}+a_{0}^{*}\left(x \ln x+\sum_{n=1}^{\infty} \frac{(-1)^{n} x^{n+1}}{n \cdot n !}\right) B) y(x)=a_{0} x+a_{0}^{*}\left(x \ln x+\sum_{n=1}^{\infty} \frac{(-1)^{n} x^{n+1}}{n \cdot n !}\right) C) y(x)=a_{0}+a^{*}{ }_{0}^{x}\left[\ln x+\sum_{n=1}^{\infty} \frac{(-1)^{n} x^{n+1}}{n \cdot n !}\right) D) y(x)=a_{0}+a_{0}^{*} \ln x\left(1+\sum_{n=1}^{\infty} \frac{(-1)^{n} x^{n+1}}{n \cdot n !}\right)$ .
Using the method of Frobenius, which of these is the general solution of this differential equation? Assume $Consider the second-order differential equation . Using the method of Frobenius, which of these is the general solution of this differential equation? Assume are arbitrary real constants. A) y(x)=a_{0}+a_{0}^{*}\left(x \ln x+\sum_{n=1}^{\infty} \frac{(-1)^{n} x^{n+1}}{n \cdot n !}\right) B) y(x)=a_{0} x+a_{0}^{*}\left(x \ln x+\sum_{n=1}^{\infty} \frac{(-1)^{n} x^{n+1}}{n \cdot n !}\right) C) y(x)=a_{0}+a^{*}{ }_{0}^{x}\left[\ln x+\sum_{n=1}^{\infty} \frac{(-1)^{n} x^{n+1}}{n \cdot n !}\right) D) y(x)=a_{0}+a_{0}^{*} \ln x\left(1+\sum_{n=1}^{\infty} \frac{(-1)^{n} x^{n+1}}{n \cdot n !}\right)$ are arbitrary real constants.

y(x)=a_{0}+a_{0}^{*}\left(x \ln x+\sum_{n=1}^{\infty} \frac{(-1)^{n} x^{n+1}}{n \cdot n !}\right)

y(x)=a_{0} x+a_{0}^{*}\left(x \ln x+\sum_{n=1}^{\infty} \frac{(-1)^{n} x^{n+1}}{n \cdot n !}\right)

y(x)=a_{0}+a^{*}{ }_{0}^{x}\left[\ln x+\sum_{n=1}^{\infty} \frac{(-1)^{n} x^{n+1}}{n \cdot n !}\right)

y(x)=a_{0}+a_{0}^{*} \ln x\left(1+\sum_{n=1}^{\infty} \frac{(-1)^{n} x^{n+1}}{n \cdot n !}\right)

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Consider the second-order differential equation .
What is the radius of convergence of the series of the general solution of the differential equation?

A) 1
B) 2
C) 4
D) ?

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= 0
B)

r -

= 0
C)

r +

= 0
D)

r -

= 0

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Consider the second-order differential equation $Consider the second-order differential equation . Suppose the method of Frobenius is used to determine the general solution of this differential equation. Which of the following is the form of a pair of linearly independent solution of this differential A) y_{1}(x)=\sum_{n=0}^{\infty} a_{n} x^{n}, y_{2}(x)=x^{-\frac{1}{4}} \sum_{n=0}^{\infty} b_{n} x^{n} B) y_{1}(x)=\sum_{n=0}^{\infty} a_{n} x^{n+1}, y_{2}(x)=x^{-\frac{1}{4}} \sum_{n=0}^{\infty} b_{n} x^{n} C) y_{1}(x)=\sum_{n=0}^{\infty} a_{n} x^{n}, y_{2}(x)=x^{\frac{3}{4}} \sum_{n=0}^{\infty} b_{n} x^{n} D) y_{1}(x)=\sum_{n=0}^{\infty} a_{n} x^{n+1}, y_{2}(x)=x^{\frac{3}{4}} \sum_{n=0}^{\infty} b_{n} x^{n} E) y_{1}(x)=\ln (x) \sum_{n=0}^{\infty} a_{n} x^{n+1}, y_{2}(x)=x^{-\frac{1}{4}} \sum_{n=0}^{\infty} b_{n} x^{n}$ .
Suppose the method of Frobenius is used to determine the general solution of this differential equation.
Which of the following is the form of a pair of linearly independent solution of this differential

y_{1}(x)=\sum_{n=0}^{\infty} a_{n} x^{n}, y_{2}(x)=x^{-\frac{1}{4}} \sum_{n=0}^{\infty} b_{n} x^{n}

y_{1}(x)=\sum_{n=0}^{\infty} a_{n} x^{n+1}, y_{2}(x)=x^{-\frac{1}{4}} \sum_{n=0}^{\infty} b_{n} x^{n}

y_{1}(x)=\sum_{n=0}^{\infty} a_{n} x^{n}, y_{2}(x)=x^{\frac{3}{4}} \sum_{n=0}^{\infty} b_{n} x^{n}

y_{1}(x)=\sum_{n=0}^{\infty} a_{n} x^{n+1}, y_{2}(x)=x^{\frac{3}{4}} \sum_{n=0}^{\infty} b_{n} x^{n}

y_{1}(x)=\ln (x) \sum_{n=0}^{\infty} a_{n} x^{n+1}, y_{2}(x)=x^{-\frac{1}{4}} \sum_{n=0}^{\infty} b_{n} x^{n}

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Consider the second-order differential equation .
Which of these is the indicial equation about the regular singular point x = 0?

A) r² - 9r - 16 = 0
B) r² - 7r + 16 = 0
C) r² + 7r + 16 = 0
D)

+ 8r - 16 = 0
E)

- 8r + 16 = 0

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Consider the second-order differential equation $Consider the second-order differential equation . Which of the following is the form of a pair of linearly independent solutions of this differential equation? A) y_{1}(x)=x^{-4} \sum_{n=0}^{\infty} a_{n} x^{n}, y_{2}(x)=\ln x\left(y_{1}(x)+x^{-4} \sum_{n=0}^{\infty} b_{n} x^{n}\right) B) y_{1}(x)=x^{4} \sum_{n=0}^{\infty} a_{n} x^{n}, y_{2}(x)=\ln x\left(y_{1}(x)+x^{4} \sum_{n=0}^{\infty} b_{n} x^{n}\right) C) y_{1}(x)=x^{-4} \sum_{n=0}^{\infty} a_{n} x^{n}, y_{2}(x)=y_{1}(x) \ln x+x^{-4} \sum_{n=0}^{\infty} b_{n} x^{n} D) \left.y_{1}(x)=x^{4} \sum_{n=0}^{\infty} a_{n} x^{n}, y_{2}(x)=y_{1} x\right) \ln x+x^{4} \sum_{n=0}^{\infty} b_{n} x^{n}$ .
Which of the following is the form of a pair of linearly independent solutions of this differential equation?

y_{1}(x)=x^{-4} \sum_{n=0}^{\infty} a_{n} x^{n}, y_{2}(x)=\ln x\left(y_{1}(x)+x^{-4} \sum_{n=0}^{\infty} b_{n} x^{n}\right)

y_{1}(x)=x^{4} \sum_{n=0}^{\infty} a_{n} x^{n}, y_{2}(x)=\ln x\left(y_{1}(x)+x^{4} \sum_{n=0}^{\infty} b_{n} x^{n}\right)

y_{1}(x)=x^{-4} \sum_{n=0}^{\infty} a_{n} x^{n}, y_{2}(x)=y_{1}(x) \ln x+x^{-4} \sum_{n=0}^{\infty} b_{n} x^{n}

\left.y_{1}(x)=x^{4} \sum_{n=0}^{\infty} a_{n} x^{n}, y_{2}(x)=y_{1} x\right) \ln x+x^{4} \sum_{n=0}^{\infty} b_{n} x^{n}

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تفوق شركة سعودية مقرها الرياض، المملكة العربية السعودية، ومرخصة بموجب سجل تجاري رقم (1009085957).