Question 1

In the previous problem, the solution of the eigenvalue problem is

Accepted Answer

A)  $\lambda = n ^ { 2 } , R = r ^ { n } , n = 0,1,2 , \ldots$ 
B)  $\lambda = n , R = r ^ { n } , n = 0,1,2 , \ldots$ 
C)  $\lambda = n , \Theta = c _ { n } \cos ( n \theta ) + d _ { n } \sin ( n \theta ) , n = 0,1,2 , .$ 
D)  $\lambda = n ^ { 2 } , \Theta = d _ { n } \sin ( n \theta ) , n = 1,2,3 , .$ 
E)  $\lambda = n ^ { 2 } , \Theta = c _ { n } \cos ( n \theta ) , n = 0,1,2 , \ldots$ 
A)  $\lambda = n ^ { 2 } , R = r ^ { n } , n = 0,1,2 , \ldots$ 
B)  $\lambda = n , R = r ^ { n } , n = 0,1,2 , \ldots$ 
C)  $\lambda = n , \Theta = c _ { n } \cos ( n \theta ) + d _ { n } \sin ( n \theta ) , n = 0,1,2 , .$ 
D)  $\lambda = n ^ { 2 } , \Theta = d _ { n } \sin ( n \theta ) , n = 1,2,3 , .$ 
E)  $\lambda = n ^ { 2 } , \Theta = c _ { n } \cos ( n \theta ) , n = 0,1,2 , \ldots$ D

Question 2

In changing from Cartesian to polar coordinates, $\frac { \partial r } { \partial y }$ is

Accepted Answer

A)  $\sin \theta$ 
B)  $\cos \theta$ 
C)  $\sin \theta / r$ 
D)  $\cos \theta / r$ 
E)  $- \sin \theta / r$ 
A)  $\sin \theta$ 
B)  $\cos \theta$ 
C)  $\sin \theta / r$ 
D)  $\cos \theta / r$ 
E)  $- \sin \theta / r$ A

Question 3

In the three previous problems, the product solutions are

Accepted Answer

A)  $u _ { n } = \left( a _ { n } r ^ { n } + b _ { n } r ^ { - n } \right) \left( c _ { n } \cos ( n \theta ) + d _ { n } \sin ( n \theta ) \right) , n = 0,1,2 , \ldots$ 
B)  $u _ { n } = r ^ { n } \left( c _ { n } \cos ( n \theta ) + d _ { n } \sin ( n \theta ) \right) , n = 1,2,3 , \ldots$ 
C)  $u _ { n } = r ^ { n } \left( c _ { n } \cos ( n \theta ) + d _ { n } \sin ( n \theta ) \right) , n = 0,1,2 , \ldots$ 
D)  $u _ { n } = r ^ { n } \left( c _ { n } e ^ { n \theta } + d _ { n } e ^ { - n \theta } \right) , n = 0,1,2 , \ldots$ 
E)  $u _ { n } = r ^ { n } \left( c _ { n } e ^ { n \theta } + d _ { n } e ^ { - n \theta } \right) , n = 1,2,3 , \ldots$ 
A)  $u _ { n } = \left( a _ { n } r ^ { n } + b _ { n } r ^ { - n } \right) \left( c _ { n } \cos ( n \theta ) + d _ { n } \sin ( n \theta ) \right) , n = 0,1,2 , \ldots$ 
B)  $u _ { n } = r ^ { n } \left( c _ { n } \cos ( n \theta ) + d _ { n } \sin ( n \theta ) \right) , n = 1,2,3 , \ldots$ 
C)  $u _ { n } = r ^ { n } \left( c _ { n } \cos ( n \theta ) + d _ { n } \sin ( n \theta ) \right) , n = 0,1,2 , \ldots$ 
D)  $u _ { n } = r ^ { n } \left( c _ { n } e ^ { n \theta } + d _ { n } e ^ { - n \theta } \right) , n = 0,1,2 , \ldots$ 
E)  $u _ { n } = r ^ { n } \left( c _ { n } e ^ { n \theta } + d _ { n } e ^ { - n \theta } \right) , n = 1,2,3 , \ldots$ C

Question 4

In the previous four problems, the infinite series solution of the original problem is (for certain values of the constants $a _ { n }$ and $b _ { n }$ )

Accepted Answer

A)  $u = \sum _ { n = 1 } ^ { \infty } a _ { n } J _ { 0 } \left( z _ { n } r / 2 \right) \cos \left( z _ { n } t / 2 \right)$ 
B)  $u = \sum _ { n = 1 } ^ { \infty } b _ { n } J _ { 0 } \left( z _ { n } r / 2 \right) \sin \left( z _ { n } t / 2 \right)$ 
C)  $u = \sum _ { n = 1 } ^ { \infty } b _ { n } J _ { 0 } ( n \pi r ) \sin ( n \pi t )$ 
D)  $u = \sum _ { n = 1 } ^ { \infty } a _ { n } J _ { 0 } ( n \pi r ) \cos ( n \pi t )$ 
E)  $u = \sum _ { n - 1 } ^ { \infty } J _ { 0 } \left( z _ { n } r / 2 \right) \left( a _ { n } \cos ( n \pi t ) + b _ { n } \sin ( n \pi t ) \right)$ 
A)  $u = \sum _ { n = 1 } ^ { \infty } a _ { n } J _ { 0 } \left( z _ { n } r / 2 \right) \cos \left( z _ { n } t / 2 \right)$ 
B)  $u = \sum _ { n = 1 } ^ { \infty } b _ { n } J _ { 0 } \left( z _ { n } r / 2 \right) \sin \left( z _ { n } t / 2 \right)$ 
C)  $u = \sum _ { n = 1 } ^ { \infty } b _ { n } J _ { 0 } ( n \pi r ) \sin ( n \pi t )$ 
D)  $u = \sum _ { n = 1 } ^ { \infty } a _ { n } J _ { 0 } ( n \pi r ) \cos ( n \pi t )$ 
E)  $u = \sum _ { n - 1 } ^ { \infty } J _ { 0 } \left( z _ { n } r / 2 \right) \left( a _ { n } \cos ( n \pi t ) + b _ { n } \sin ( n \pi t ) \right)$

Question 5

In the previous problem, separate variables using $u ( r , \theta ) = R ( r ) \Theta ( \theta )$ . The resulting problems are

Accepted Answer

A)  $r ^ { 2 } R ^ { \prime \prime } + r R ^ { \prime } - \lambda R = 0 , \Theta ^ { \prime \prime } - \lambda \Theta = 0 , \Theta ( \theta ) = \Theta ( \theta + 2 \pi )$ 
B)  $r ^ { 2 } R ^ { \prime \prime } + r R ^ { \prime } + \lambda R = 0 , \Theta ^ { \prime \prime } + \lambda \Theta = 0 , \Theta ( \theta ) = \Theta ( \theta + 2 \pi )$ 
C)  $r ^ { 2 } R ^ { \prime \prime } + r R ^ { \prime } - \lambda R = 0 , \Theta ^ { \prime \prime } + \lambda \Theta = 0 , \Theta ( \theta ) = \Theta ( \theta + 2 \pi )$ 
D)  $r ^ { 2 } R ^ { \prime \prime } + r R ^ { \prime } - \lambda R = 0 , \Theta ^ { \prime \prime } + \lambda \Theta = 0 , \Theta ( \theta ) = \Theta ( \theta + \pi )$ 
E)  $r ^ { 2 } R ^ { \prime \prime } + r R ^ { \prime } + \lambda R = 0 , \Theta ^ { \prime \prime } + \lambda \Theta = 0 , \Theta ( \theta ) = \Theta ( \theta + \pi )$ 
A)  $r ^ { 2 } R ^ { \prime \prime } + r R ^ { \prime } - \lambda R = 0 , \Theta ^ { \prime \prime } - \lambda \Theta = 0 , \Theta ( \theta ) = \Theta ( \theta + 2 \pi )$ 
B)  $r ^ { 2 } R ^ { \prime \prime } + r R ^ { \prime } + \lambda R = 0 , \Theta ^ { \prime \prime } + \lambda \Theta = 0 , \Theta ( \theta ) = \Theta ( \theta + 2 \pi )$ 
C)  $r ^ { 2 } R ^ { \prime \prime } + r R ^ { \prime } - \lambda R = 0 , \Theta ^ { \prime \prime } + \lambda \Theta = 0 , \Theta ( \theta ) = \Theta ( \theta + 2 \pi )$ 
D)  $r ^ { 2 } R ^ { \prime \prime } + r R ^ { \prime } - \lambda R = 0 , \Theta ^ { \prime \prime } + \lambda \Theta = 0 , \Theta ( \theta ) = \Theta ( \theta + \pi )$ 
E)  $r ^ { 2 } R ^ { \prime \prime } + r R ^ { \prime } + \lambda R = 0 , \Theta ^ { \prime \prime } + \lambda \Theta = 0 , \Theta ( \theta ) = \Theta ( \theta + \pi )$

Question 6

In changing from Cartesian to polar coordinates, $\frac { \partial r } { \partial x }$ is

Accepted Answer

A)  $\sin \theta$ 
B)  $\cos \theta$ 
C)  $\sin \theta / r$ 
D)  $\cos \theta / r$ 
E)  $- \sin \theta / r$ 
A)  $\sin \theta$ 
B)  $\cos \theta$ 
C)  $\sin \theta / r$ 
D)  $\cos \theta / r$ 
E)  $- \sin \theta / r$

Question 7

In the previous problem, if we also require that $\Theta$ be bounded everywhere, the solution of the eigenvalue problem is

Accepted Answer

A)  $\lambda = n ( n + 1 ) , \Theta = P _ { n } ( \sin \theta ) , n = 1,2,3 , \ldots$ 
B)  $\lambda = n ( n - 1 ) , \Theta = \sin ( n \theta ) , n = 1,2,3 , \ldots$ 
C)  $\lambda = n ( n - 1 ) , \Theta = \cos ( n \theta ) , n = 1,2,3 , \ldots$ 
D)  $\lambda = n ( n + 1 ) , \Theta = P _ { n } ( \cos \theta ) , n = 1,2,3 , \ldots$ 
E)  $\lambda = n ( n - 1 ) , \Theta = P _ { n } ( \sin \theta ) , n = 1,2,3 , \ldots$ 
A)  $\lambda = n ( n + 1 ) , \Theta = P _ { n } ( \sin \theta ) , n = 1,2,3 , \ldots$ 
B)  $\lambda = n ( n - 1 ) , \Theta = \sin ( n \theta ) , n = 1,2,3 , \ldots$ 
C)  $\lambda = n ( n - 1 ) , \Theta = \cos ( n \theta ) , n = 1,2,3 , \ldots$ 
D)  $\lambda = n ( n + 1 ) , \Theta = P _ { n } ( \cos \theta ) , n = 1,2,3 , \ldots$ 
E)  $\lambda = n ( n - 1 ) , \Theta = P _ { n } ( \sin \theta ) , n = 1,2,3 , \ldots$

Question 8

In the previous four problems, the infinite series solution of the original problem is $u = A _ { 0 } + \sum _ { n = 1 } ^ { \infty } r ^ { n } \left( A _ { n } \cos ( n \theta ) + B _ { n } \sin ( n \theta ) \right)$ where Select all that apply.

Accepted Answer

A)  $A _ { 0 } = \int _ { 0 } ^ { 2 \pi } f ( \theta ) d \theta l ( 2 \pi )$ 
B)  $A _ { n } = \int _ { 0 } ^ { 2 \pi } f ( \theta ) \sin ( n \theta ) d \theta / \left( c ^ { n } \pi \right)$ 
C)  $A _ { n } = \int _ { 0 } ^ { 2 \pi } f ( \theta ) \cos ( n \theta ) d \theta / \left( c ^ { n } \pi \right)$ 
D)  $B _ { n } = \int _ { 0 } ^ { 2 \pi } f ( \theta ) \sin ( n \theta ) d \theta / \left( c ^ { n } \pi \right)$ 
E)  $B _ { n } = \int _ { 0 } ^ { 2 \pi } f ( \theta ) \cos ( n \theta ) d \theta / \left( c ^ { n } \pi \right)$ 
A)  $A _ { 0 } = \int _ { 0 } ^ { 2 \pi } f ( \theta ) d \theta l ( 2 \pi )$ 
B)  $A _ { n } = \int _ { 0 } ^ { 2 \pi } f ( \theta ) \sin ( n \theta ) d \theta / \left( c ^ { n } \pi \right)$ 
C)  $A _ { n } = \int _ { 0 } ^ { 2 \pi } f ( \theta ) \cos ( n \theta ) d \theta / \left( c ^ { n } \pi \right)$ 
D)  $B _ { n } = \int _ { 0 } ^ { 2 \pi } f ( \theta ) \sin ( n \theta ) d \theta / \left( c ^ { n } \pi \right)$ 
E)  $B _ { n } = \int _ { 0 } ^ { 2 \pi } f ( \theta ) \cos ( n \theta ) d \theta / \left( c ^ { n } \pi \right)$

Question 9

When changing from Cartesian to spherical coordinates, $\frac { \partial r } { \partial z } =$

Accepted Answer

A)  $\cos \phi$ 
B)  $\cos \theta$ 
C)  $\tan \theta$ 
D)  $\sin \phi$ 
E)  $\sin \theta$ 
A)  $\cos \phi$ 
B)  $\cos \theta$ 
C)  $\tan \theta$ 
D)  $\sin \phi$ 
E)  $\sin \theta$

Question 10

Using the separation of the previous problem, the equation for $\Theta$ becomes

Accepted Answer

A)  $\Theta ^ { \prime \prime } - \lambda \Theta = 0$ 
B)  $\Theta ^ { \prime \prime } + \lambda \Theta = 0$ 
C)  $\sin ( \theta ) \Theta ^ { \prime \prime } + \cos ( \theta ) \Theta ^ { \prime } + \lambda \sin ( \theta ) \Theta = 0$ 
D)  $\cos ( \theta ) \Theta ^ { \prime \prime } - \sin ( \theta ) \Theta ^ { \prime } + \lambda \sin ( \theta ) \Theta = 0$ 
E)  $\sin ( \theta ) \Theta ^ { \prime \prime } - \cos ( \theta ) \Theta ^ { \prime } + \lambda \sin ( \theta ) \Theta = 0$ 
A)  $\Theta ^ { \prime \prime } - \lambda \Theta = 0$ 
B)  $\Theta ^ { \prime \prime } + \lambda \Theta = 0$ 
C)  $\sin ( \theta ) \Theta ^ { \prime \prime } + \cos ( \theta ) \Theta ^ { \prime } + \lambda \sin ( \theta ) \Theta = 0$ 
D)  $\cos ( \theta ) \Theta ^ { \prime \prime } - \sin ( \theta ) \Theta ^ { \prime } + \lambda \sin ( \theta ) \Theta = 0$ 
E)  $\sin ( \theta ) \Theta ^ { \prime \prime } - \cos ( \theta ) \Theta ^ { \prime } + \lambda \sin ( \theta ) \Theta = 0$

Question 11

In the problem $\frac { \partial ^ { 2 } u } { \partial r ^ { 2 } } + \frac { 2 } { r } \frac { \partial u } { \partial r } + \frac { 1 } { r ^ { 2 } } \frac { \partial ^ { 2 } u } { \partial \theta ^ { 2 } } + \frac { \cot \theta } { r ^ { 2 } } \frac { \partial u } { \partial \theta } = 0$ , separate variables, using $u ( r , \theta ) = R ( r ) \Theta ( \theta )$ . The resulting problems for $R$ and $\Theta$ are

Accepted Answer

A)  $r ^ { 2 } R ^ { \prime \prime } + 2 r R ^ { \prime } + \lambda R = 0 , R ( 0 )$ is bounded; $\sin ( \theta ) \Theta ^ { \prime \prime } + \cos ( \theta ) \Theta ^ { \prime } + \lambda \sin ( \theta ) \Theta = 0,\Theta$ is bounded on $[ 0 , \pi ]$ . 
B)  $r ^ { 2 } R ^ { \prime \prime } + 2 r R ^ { \prime } - \lambda R = 0 , R ( 0 )$ is bounded; $\sin ( \theta ) \Theta ^ { \prime \prime } + \cos ( \theta ) \Theta ^ { \prime } + \lambda \sin ( \theta ) \Theta = 0,\Theta$ is bounded on $[ 0 , \pi ]$ . 
C)  $r ^ { 2 } R ^ { \prime \prime } + 2 r R ^ { \prime } - \lambda R = 0 , R ( 0 )$ is bounded; $\sin ( \theta ) \Theta ^ { \prime \prime } + \cos ( \theta ) \Theta ^ { \prime } - \lambda \sin ( \theta ) \Theta = 0,\Theta$ is bounded on $[ 0 , \pi ]$ . 
D)  $r ^ { 2 } R ^ { \prime \prime } - 2 r R ^ { \prime } - \lambda R = 0 , R ( 0 )$ is bounded; $\sin ( \theta ) \Theta ^ { \prime \prime } + \cos ( \theta ) \Theta ^ { \prime } + \lambda \sin ( \theta ) \Theta = 0,\Theta$ is bounded on $[ 0 , \pi ]$ . 
E)  $r ^ { 2 } R ^ { \prime \prime } + 2 r R ^ { \prime } - \lambda R = 0 , R ( 0 )$ is bounded; $\sin ( \theta ) \Theta ^ { \prime \prime } - \cos ( \theta ) \Theta ^ { \prime } + \lambda \sin ( \theta ) \Theta = 0,\Theta$ is bounded on $[ 0 , \pi ]$ . 
A)  $r ^ { 2 } R ^ { \prime \prime } + 2 r R ^ { \prime } + \lambda R = 0 , R ( 0 )$ is bounded; $\sin ( \theta ) \Theta ^ { \prime \prime } + \cos ( \theta ) \Theta ^ { \prime } + \lambda \sin ( \theta ) \Theta = 0,\Theta$ is bounded on $[ 0 , \pi ]$ . 
B)  $r ^ { 2 } R ^ { \prime \prime } + 2 r R ^ { \prime } - \lambda R = 0 , R ( 0 )$ is bounded; $\sin ( \theta ) \Theta ^ { \prime \prime } + \cos ( \theta ) \Theta ^ { \prime } + \lambda \sin ( \theta ) \Theta = 0,\Theta$ is bounded on $[ 0 , \pi ]$ . 
C)  $r ^ { 2 } R ^ { \prime \prime } + 2 r R ^ { \prime } - \lambda R = 0 , R ( 0 )$ is bounded; $\sin ( \theta ) \Theta ^ { \prime \prime } + \cos ( \theta ) \Theta ^ { \prime } - \lambda \sin ( \theta ) \Theta = 0,\Theta$ is bounded on $[ 0 , \pi ]$ . 
D)  $r ^ { 2 } R ^ { \prime \prime } - 2 r R ^ { \prime } - \lambda R = 0 , R ( 0 )$ is bounded; $\sin ( \theta ) \Theta ^ { \prime \prime } + \cos ( \theta ) \Theta ^ { \prime } + \lambda \sin ( \theta ) \Theta = 0,\Theta$ is bounded on $[ 0 , \pi ]$ . 
E)  $r ^ { 2 } R ^ { \prime \prime } + 2 r R ^ { \prime } - \lambda R = 0 , R ( 0 )$ is bounded; $\sin ( \theta ) \Theta ^ { \prime \prime } - \cos ( \theta ) \Theta ^ { \prime } + \lambda \sin ( \theta ) \Theta = 0,\Theta$ is bounded on $[ 0 , \pi ]$ .

Question 12

In changing from Cartesian to polar coordinates, $\frac { \partial u } { \partial y }$ is

Accepted Answer

A)  $\cos \theta \frac { \partial u } { \partial r } - \sin \theta \frac { \partial u } { \partial \theta } / r$ 
B)  $\cos \theta \frac { \partial u } { \partial r } + \cos \theta \frac { \partial u } { \partial \theta } / r$ 
C)  $\sin \theta \frac { \partial u } { \partial r } + \cos \theta \frac { \partial u } { \partial \theta }$ 
D)  $\sin \theta \frac { \partial u } { \partial r } + \cos \theta \frac { \partial u } { \partial \theta } / r$ 
E)  $\sin \theta \frac { \partial u } { \partial r } - \cos \theta \frac { \partial u } { \partial \theta } / r$ 
A)  $\cos \theta \frac { \partial u } { \partial r } - \sin \theta \frac { \partial u } { \partial \theta } / r$ 
B)  $\cos \theta \frac { \partial u } { \partial r } + \cos \theta \frac { \partial u } { \partial \theta } / r$ 
C)  $\sin \theta \frac { \partial u } { \partial r } + \cos \theta \frac { \partial u } { \partial \theta }$ 
D)  $\sin \theta \frac { \partial u } { \partial r } + \cos \theta \frac { \partial u } { \partial \theta } / r$ 
E)  $\sin \theta \frac { \partial u } { \partial r } - \cos \theta \frac { \partial u } { \partial \theta } / r$

Question 13

When changing from Cartesian to spherical coordinates, $\frac { \partial \phi } { \partial x } =$

Accepted Answer

A)  $- \sin \phi / ( r \sin \theta )$ 
B)  $\sin \phi / ( r \sin \theta )$ 
C)  $- \cos \phi / ( r \sin \theta )$ 
D)  $\cos \phi / ( r \cos \theta )$ 
E)  $\sin \phi / ( r \cos \theta )$ 
A)  $- \sin \phi / ( r \sin \theta )$ 
B)  $\sin \phi / ( r \sin \theta )$ 
C)  $- \cos \phi / ( r \sin \theta )$ 
D)  $\cos \phi / ( r \cos \theta )$ 
E)  $\sin \phi / ( r \cos \theta )$

Question 14

In the previous three problems, the product solutions are

Accepted Answer

A)  $u = J _ { 0 } \left( z _ { n } r / 2 \right) \left( a _ { n } \cos \left( z _ { n } t / 2 \right) + b _ { n } \sin \left( z _ { n } t / 2 \right) \right)$ 
B)  $u = J _ { 0 } \left( z _ { n } r / 2 \right) a _ { n } \cos \left( z _ { n } t / 2 \right)$ 
C)  $u = J _ { 0 } \left( z _ { n } r / 2 \right) b _ { n } \sin \left( z _ { n } t / 2 \right)$ 
D)  $u = J _ { 0 } ( n \pi r ) b _ { n } \sin ( n \pi i )$ 
E)  $u = J _ { 0 } ( n \pi r ) a _ { n } \cos ( n \pi i )$ 
A)  $u = J _ { 0 } \left( z _ { n } r / 2 \right) \left( a _ { n } \cos \left( z _ { n } t / 2 \right) + b _ { n } \sin \left( z _ { n } t / 2 \right) \right)$ 
B)  $u = J _ { 0 } \left( z _ { n } r / 2 \right) a _ { n } \cos \left( z _ { n } t / 2 \right)$ 
C)  $u = J _ { 0 } \left( z _ { n } r / 2 \right) b _ { n } \sin \left( z _ { n } t / 2 \right)$ 
D)  $u = J _ { 0 } ( n \pi r ) b _ { n } \sin ( n \pi i )$ 
E)  $u = J _ { 0 } ( n \pi r ) a _ { n } \cos ( n \pi i )$

Question 15

The equations relating Cartesian and spherical coordinates include Select all that apply.

Accepted Answer

A)  $y = r \cos \phi \cos \theta$ 
B)  $x = r \cos \phi \sin \theta$ 
C)  $r ^ { 2 } = x ^ { 2 } + y ^ { 2 } + z ^ { 2 }$ 
D)  $z = r \cos \theta$ 
E)  $\tan \phi = y / x$ 
A)  $y = r \cos \phi \cos \theta$ 
B)  $x = r \cos \phi \sin \theta$ 
C)  $r ^ { 2 } = x ^ { 2 } + y ^ { 2 } + z ^ { 2 }$ 
D)  $z = r \cos \theta$ 
E)  $\tan \phi = y / x$

Question 16

The solution of $r ^ { 2 } R ^ { \prime \prime } + r R ^ { \prime } + \lambda R = 0 , R ( 1 ) = 0 , R ( 2 ) = 0$ is

Accepted Answer

A)  $\lambda = n \pi / \ln 2 , R = \sin ( n \pi \ln r / \ln 2 )$ 
B)  $\lambda = ( n \pi / \ln 2 ) ^ { 2 } , R = \sin ( n \pi \ln r / \ln 2 )$ 
C)  $\lambda = ( n \pi / \ln 2 ) ^ { 2 } , R = \cos ( n \pi \ln r / \ln 2 )$ 
D)  $\lambda = n \pi / \ln 2 , R = \cos ( n \pi \ln r / \ln 2 )$ 
E)  none of the above 
A)  $\lambda = n \pi / \ln 2 , R = \sin ( n \pi \ln r / \ln 2 )$ 
B)  $\lambda = ( n \pi / \ln 2 ) ^ { 2 } , R = \sin ( n \pi \ln r / \ln 2 )$ 
C)  $\lambda = ( n \pi / \ln 2 ) ^ { 2 } , R = \cos ( n \pi \ln r / \ln 2 )$ 
D)  $\lambda = n \pi / \ln 2 , R = \cos ( n \pi \ln r / \ln 2 )$ 
E)  none of the above

Question 17

Consider the steady-state temperature distribution in a circular disc of radius $C$ centere at the origin, with temperature given as a function, $f ( \theta )$ on the boundary $r = c$ and zero on the boundaries $\theta = 0$ and $\theta = \pi$ The mathematical model of this situation is

Accepted Answer

A)  $\frac { \partial ^ { 2 } u } { \partial r ^ { 2 } } - \frac { 1 } { r } \frac { \partial u } { \partial r } + \frac { 1 } { r ^ { 2 } } \frac { \partial ^ { 2 } u } { \partial \theta ^ { 2 } } = 0 , u ( c , \theta ) = f ( \theta ) , u ( r , 0 ) = 0 , u ( r , \pi ) = 0$ 
B)  $\frac { \partial ^ { 2 } u } { \partial r ^ { 2 } } + \frac { 1 } { r } \frac { \partial u } { \partial r } - \frac { 1 } { r ^ { 2 } } \frac { \partial ^ { 2 } u } { \partial \theta ^ { 2 } } = 0 , u ( c , \theta ) = f ( \theta ) , u ( r , 0 ) = 0 , u ( r , \pi ) = 0$ 
C)  $\frac { \partial ^ { 2 } u } { \partial r ^ { 2 } } - \frac { 1 } { r } \frac { \partial u } { \partial r } - \frac { 1 } { r ^ { 2 } } \frac { \partial ^ { 2 } u } { \partial \theta ^ { 2 } } = 0 , u ( c , \theta ) = f ( \theta ) , u ( r , 0 ) = 0 , u ( r , \pi ) = 0$ 
D)  $\frac { \partial ^ { 2 } u } { \partial r ^ { 2 } } + \frac { 1 } { r ^ { 2 } } \frac { \partial u } { \partial r } + \frac { 1 } { r } \frac { \partial ^ { 2 } u } { \partial \theta ^ { 2 } } = 0 , u ( c , \theta ) = f ( \theta ) , u ( r , 0 ) = 0 , u ( r , \pi ) = 0$ 
E)  $\frac { \partial ^ { 2 } u } { \partial r ^ { 2 } } + \frac { 1 } { r } \frac { \partial u } { \partial r } + \frac { 1 } { r ^ { 2 } } \frac { \partial ^ { 2 } u } { \partial \theta ^ { 2 } } = 0 , u ( c , \theta ) = f ( \theta ) , u ( r , 0 ) = 0 , u ( r , \pi ) = 0$ 
A)  $\frac { \partial ^ { 2 } u } { \partial r ^ { 2 } } - \frac { 1 } { r } \frac { \partial u } { \partial r } + \frac { 1 } { r ^ { 2 } } \frac { \partial ^ { 2 } u } { \partial \theta ^ { 2 } } = 0 , u ( c , \theta ) = f ( \theta ) , u ( r , 0 ) = 0 , u ( r , \pi ) = 0$ 
B)  $\frac { \partial ^ { 2 } u } { \partial r ^ { 2 } } + \frac { 1 } { r } \frac { \partial u } { \partial r } - \frac { 1 } { r ^ { 2 } } \frac { \partial ^ { 2 } u } { \partial \theta ^ { 2 } } = 0 , u ( c , \theta ) = f ( \theta ) , u ( r , 0 ) = 0 , u ( r , \pi ) = 0$ 
C)  $\frac { \partial ^ { 2 } u } { \partial r ^ { 2 } } - \frac { 1 } { r } \frac { \partial u } { \partial r } - \frac { 1 } { r ^ { 2 } } \frac { \partial ^ { 2 } u } { \partial \theta ^ { 2 } } = 0 , u ( c , \theta ) = f ( \theta ) , u ( r , 0 ) = 0 , u ( r , \pi ) = 0$ 
D)  $\frac { \partial ^ { 2 } u } { \partial r ^ { 2 } } + \frac { 1 } { r ^ { 2 } } \frac { \partial u } { \partial r } + \frac { 1 } { r } \frac { \partial ^ { 2 } u } { \partial \theta ^ { 2 } } = 0 , u ( c , \theta ) = f ( \theta ) , u ( r , 0 ) = 0 , u ( r , \pi ) = 0$ 
E)  $\frac { \partial ^ { 2 } u } { \partial r ^ { 2 } } + \frac { 1 } { r } \frac { \partial u } { \partial r } + \frac { 1 } { r ^ { 2 } } \frac { \partial ^ { 2 } u } { \partial \theta ^ { 2 } } = 0 , u ( c , \theta ) = f ( \theta ) , u ( r , 0 ) = 0 , u ( r , \pi ) = 0$

Question 18

In the previous three problems, the solution for $R$ is

Accepted Answer

A)  $R = r ^ { n }$ 
B)  $R = r ^ { - n - 1 }$ 
C)  $R = c _ { 1 } r ^ { n } + c _ { 2 } r ^ { - n - 1 }$ 
D)  $R = c _ { 1 } r ^ { n } + c _ { 2 } r ^ { n + 1 }$ 
E)  $R = c _ { 1 } r ^ { n } + c _ { 2 } r ^ { n - 1 }$ 
A)  $R = r ^ { n }$ 
B)  $R = r ^ { - n - 1 }$ 
C)  $R = c _ { 1 } r ^ { n } + c _ { 2 } r ^ { - n - 1 }$ 
D)  $R = c _ { 1 } r ^ { n } + c _ { 2 } r ^ { n + 1 }$ 
E)  $R = c _ { 1 } r ^ { n } + c _ { 2 } r ^ { n - 1 }$

Question 19

In the previous problem, the solution of the eigenvalue problem is

Accepted Answer

A)  $\lambda = n \pi , T = a _ { n } \cos ( n \pi i ) + b _ { n } \sin ( n \pi t )$ 
B)  $\lambda = n ^ { 2 } \pi ^ { 2 } , T = a _ { n } \cos ( n \pi t ) + b _ { n } \sin ( n \pi t )$ 
C)  $\lambda = z _ { n } ^ { 2 } / 4$ , where $J _ { 0 } \left( z _ { n } \right) = 0 , R = J _ { 0 } \left( z _ { n } r / 2 \right)$ 
D)  $\lambda = z _ { n } / 2$ , where $J _ { 0 } \left( z _ { n } \right) = 0 , R = J _ { 0 } \left( z _ { n } r / 2 \right)$ 
E)  $\lambda = z _ { n } ^ { 2 }$ , where $J _ { 0 } \left( z _ { n } \right) = 0 , R = J _ { 0 } \left( z _ { n } r \right)$ 
A)  $\lambda = n \pi , T = a _ { n } \cos ( n \pi i ) + b _ { n } \sin ( n \pi t )$ 
B)  $\lambda = n ^ { 2 } \pi ^ { 2 } , T = a _ { n } \cos ( n \pi t ) + b _ { n } \sin ( n \pi t )$ 
C)  $\lambda = z _ { n } ^ { 2 } / 4$ , where $J _ { 0 } \left( z _ { n } \right) = 0 , R = J _ { 0 } \left( z _ { n } r / 2 \right)$ 
D)  $\lambda = z _ { n } / 2$ , where $J _ { 0 } \left( z _ { n } \right) = 0 , R = J _ { 0 } \left( z _ { n } r / 2 \right)$ 
E)  $\lambda = z _ { n } ^ { 2 }$ , where $J _ { 0 } \left( z _ { n } \right) = 0 , R = J _ { 0 } \left( z _ { n } r \right)$

Question 20

In separating variables, using, $u ( r , \theta ) = R ( r ) \Theta ( \theta )$ , in the equation $\frac { \partial ^ { 2 } u } { \partial r ^ { 2 } } + \frac { 2 } { r } \frac { \partial u } { \partial r } + \frac { 1 } { r ^ { 2 } } \frac { \partial ^ { 2 } u } { \partial \theta ^ { 2 } } + \frac { \cot \theta } { r ^ { 2 } } \frac { \partial u } { \partial \theta } = 0$ , the resulting equation for $R$ and is

Accepted Answer

A)  $r ^ { 2 } R ^ { \prime \prime } + 2 r R ^ { \prime } - \lambda R = 0$ 
B)  $r ^ { 2 } R ^ { \prime \prime } - 2 r R ^ { \prime } - \lambda R = 0$ 
C)  $r R ^ { \prime \prime } + 2 r R ^ { \prime } - \lambda r R = 0$ 
D)  $r R ^ { \prime \prime } + 2 R ^ { \prime } - \lambda r R = 0$ 
E)  $r ^ { 2 } R ^ { \prime \prime } - 2 r R ^ { \prime } - \lambda r R = 0$ 
A)  $r ^ { 2 } R ^ { \prime \prime } + 2 r R ^ { \prime } - \lambda R = 0$ 
B)  $r ^ { 2 } R ^ { \prime \prime } - 2 r R ^ { \prime } - \lambda R = 0$ 
C)  $r R ^ { \prime \prime } + 2 r R ^ { \prime } - \lambda r R = 0$ 
D)  $r R ^ { \prime \prime } + 2 R ^ { \prime } - \lambda r R = 0$ 
E)  $r ^ { 2 } R ^ { \prime \prime } - 2 r R ^ { \prime } - \lambda r R = 0$

In the previous problem, the solution of the eigenvalue problem is

In changing from Cartesian to polar coordinates, $\frac { \partial r } { \partial y }$ is

In the three previous problems, the product solutions are

In the previous four problems, the infinite series solution of the original problem is (for certain values of the constants $a _ { n }$ and $b _ { n }$ )

In the previous problem, separate variables using $u ( r , \theta ) = R ( r ) \Theta ( \theta )$ . The resulting problems are

In changing from Cartesian to polar coordinates, $\frac { \partial r } { \partial x }$ is

In the previous problem, if we also require that $\Theta$ be bounded everywhere, the solution of the eigenvalue problem is

In the previous four problems, the infinite series solution of the original problem is $u = A _ { 0 } + \sum _ { n = 1 } ^ { \infty } r ^ { n } \left( A _ { n } \cos ( n \theta ) + B _ { n } \sin ( n \theta ) \right)$ where Select all that apply.

When changing from Cartesian to spherical coordinates, $\frac { \partial r } { \partial z } =$

Using the separation of the previous problem, the equation for $\Theta$ becomes

In changing from Cartesian to polar coordinates, $\frac { \partial u } { \partial y }$ is

When changing from Cartesian to spherical coordinates, $\frac { \partial \phi } { \partial x } =$

In the previous three problems, the product solutions are

The equations relating Cartesian and spherical coordinates include Select all that apply.

The solution of $r ^ { 2 } R ^ { \prime \prime } + r R ^ { \prime } + \lambda R = 0 , R ( 1 ) = 0 , R ( 2 ) = 0$ is

Consider the steady-state temperature distribution in a circular disc of radius $C$ centere at the origin, with temperature given as a function, $f ( \theta )$ on the boundary $r = c$ and zero on the boundaries $\theta = 0$ and $\theta = \pi$ The mathematical model of this situation is

In the previous three problems, the solution for $R$ is

In the previous problem, the solution of the eigenvalue problem is

Introduction to Differential Equations

First-Order Differential Equations

Modeling With First-Order Differential Equations

Higher-Order Differential Equations

Modeling With Higher-Order Differential Equations

Series Solutions of Linear Equations

Laplace Transform

Systems of Linear First-Order Differential Equations

Numerical Solutions of Ordinary Differential Equations

Plane Autonomous Systems

Orthogonal Functions and Fourier Series

Boundary-Value Problems in Rectangular Coordinates

Integral Transform Method

Numerical Solutions of Partial Differential Equations

Mathematics Problems: Differential Equations and Linear Algebra

Mathematical Problems and Solutions

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Exam 13: Boundary-Value Problems in Other Coordinate Systems

In the previous problem, the solution of the eigenvalue problem is

In changing from Cartesian to polar coordinates, ∂r∂y\frac { \partial r } { \partial y }∂y∂r​ is

In the three previous problems, the product solutions are

In the previous four problems, the infinite series solution of the original problem is (for certain values of the constants ana _ { n }an​ and bnb _ { n }bn​ )

In the previous problem, separate variables using u(r,θ)=R(r)Θ(θ)u ( r , \theta ) = R ( r ) \Theta ( \theta )u(r,θ)=R(r)Θ(θ) . The resulting problems are

In changing from Cartesian to polar coordinates, ∂r∂x\frac { \partial r } { \partial x }∂x∂r​ is

In the previous problem, if we also require that Θ\ThetaΘ be bounded everywhere, the solution of the eigenvalue problem is

When changing from Cartesian to spherical coordinates, ∂r∂z=\frac { \partial r } { \partial z } =∂z∂r​=

Using the separation of the previous problem, the equation for Θ\ThetaΘ becomes

In changing from Cartesian to polar coordinates, ∂u∂y\frac { \partial u } { \partial y }∂y∂u​ is

When changing from Cartesian to spherical coordinates, ∂ϕ∂x=\frac { \partial \phi } { \partial x } =∂x∂ϕ​=

In the previous three problems, the product solutions are

The equations relating Cartesian and spherical coordinates include Select all that apply.

The solution of r2R′′+rR′+λR=0,R(1)=0,R(2)=0r ^ { 2 } R ^ { \prime \prime } + r R ^ { \prime } + \lambda R = 0 , R ( 1 ) = 0 , R ( 2 ) = 0r2R′′+rR′+λR=0,R(1)=0,R(2)=0 is

In the previous three problems, the solution for RRR is

In the previous problem, the solution of the eigenvalue problem is

Introduction to Differential Equations

First-Order Differential Equations

Modeling With First-Order Differential Equations

Higher-Order Differential Equations

Modeling With Higher-Order Differential Equations

Series Solutions of Linear Equations

Laplace Transform

Systems of Linear First-Order Differential Equations

Numerical Solutions of Ordinary Differential Equations

Plane Autonomous Systems

Orthogonal Functions and Fourier Series

Boundary-Value Problems in Rectangular Coordinates

Integral Transform Method

Numerical Solutions of Partial Differential Equations

Mathematics Problems: Differential Equations and Linear Algebra

Mathematical Problems and Solutions

Filters

In changing from Cartesian to polar coordinates, $\frac { \partial r } { \partial y }$ is

In the previous four problems, the infinite series solution of the original problem is (for certain values of the constants $a _ { n }$ and $b _ { n }$ )

In the previous problem, separate variables using $u ( r , \theta ) = R ( r ) \Theta ( \theta )$ . The resulting problems are

In changing from Cartesian to polar coordinates, $\frac { \partial r } { \partial x }$ is

In the previous problem, if we also require that $\Theta$ be bounded everywhere, the solution of the eigenvalue problem is

When changing from Cartesian to spherical coordinates, $\frac { \partial r } { \partial z } =$

Using the separation of the previous problem, the equation for $\Theta$ becomes

In changing from Cartesian to polar coordinates, $\frac { \partial u } { \partial y }$ is

When changing from Cartesian to spherical coordinates, $\frac { \partial \phi } { \partial x } =$

The solution of $r ^ { 2 } R ^ { \prime \prime } + r R ^ { \prime } + \lambda R = 0 , R ( 1 ) = 0 , R ( 2 ) = 0$ is

In the previous three problems, the solution for $R$ is