Question 1

When entering the number $1 / 7$ into a three digit base ten calculator, the round-off error is&#10;A) 0.00143&#10;B) 0.000143&#10;C) $1 / 70$&#10;D) $1 / 700$&#10;E) $1 / 7000$

Accepted Answer

$1 / 7000$&#10;

Question 2

In the previous problem, the local truncation error in $y _ { n + 1 }$ is&#10;A) $0.005 y ^ { \prime \prime } ( c ) \text {, where } x _ { n } < c < x _ { n + 1 }$&#10;B) $0.05 y ^ { \prime \prime } ( c ) \text {, where } x _ { n } < c < x _ { n + 1 }$&#10;C) $0.005 y ^ { \prime \prime } ( c ) \text {, where } x _ { n - 1 } < c < x _ { n }$&#10;D) $0.05 y ^ { \prime \prime } ( c ) \text {, where } x _ { n - 1 } < c < x _ { n }$&#10;E) unknown

Accepted Answer

The local truncation error in numerical methods for solving differential equations is often related to the derivative of the solution at a point within the interval of interest. Choice A correctly identifies the magnitude of the error and specifies that the point $c$ where the second derivative is evaluated lies between $x_n$ and $x_{n+1}$, which is consistent with the typical form of local truncation error expressions in numerical analysis.

Question 3

The improved Euler's method is what type of Runge-Kutta method?&#10;A) first order&#10;B) second order&#10;C) third order&#10;D) fourth order&#10;E) It is not a Runge-Kutta method

Accepted Answer

The improved Euler's method is a second-order Runge-Kutta method. It is also known as the Heun's method.

Question 4

The most popular fourth order Runge-Kutta method for the solution of $y ^ { t } = f ( x , y ) , y \left( x _ { 0 } \right) = y _ { 0 }$ is&#10;A) $\begin{array} { l } &#10;y _ { n + 1 } = y _ { n } + h \left( 2 k _ { 1 } + k _ { 2 } + k _ { 3 } + 2 k _ { 4 } \right) / 6 , \text { where } k _ { 1 } = f \left( x _ { n } , y _ { n } \right) , \&#10;k _ { 2 } = f \left( x _ { n } + h / 2 , y _ { n } + h k _ { 1 } / 2 \right) , k _ { 3 } = f \left( x _ { n } + h / 2 , y _ { n } + h k _ { 2 } / 2 \right) , \&#10;k _ { 4 } = f \left( x _ { n } + h , y _ { n } + h k _ { 3 } \right)&#10;\end{array}$&#10;B) $\begin{array} { l } &#10;y _ { n + 1 } = y _ { n } + h \left( k _ { 1 } + 2 k _ { 2 } + 2 k _ { 3 } + k _ { 4 } \right) / 6 , \text { where } k _ { 1 } = f \left( x _ { n } , y _ { n } \right) , \&#10;k _ { 2 } = f \left( x _ { n } + h / 2 , y _ { n } + h k _ { 1 } \right) , k _ { 3 } = f \left( x _ { n } + h / 2 , y _ { n } + h k _ { 2 } \right) , \&#10;k _ { 4 } = f \left( x _ { n } + h , y _ { n } + h k _ { 3 } \right)&#10;\end{array}$&#10;C) $\begin{array} { l } &#10;y _ { n + 1 } = y _ { n } + h \left( k _ { 1 } + 2 k _ { 2 } + 2 k _ { 3 } + k _ { 4 } \right) / 6 , \text { where } k _ { 1 } = f \left( x _ { n } , y _ { n } \right) , \&#10;k _ { 2 } = f \left( x _ { n } + h / 2 , y _ { n } + h k _ { 1 } / 2 \right) , k _ { 3 } = f \left( x _ { n } + h / 2 , y _ { n } + h k _ { 2 } / 2 \right) , \&#10;k _ { 4 } = f \left( x _ { n } + h , y _ { n } + h k _ { 3 } \right)&#10;\end{array}$&#10;D) $\begin{array} { l } &#10;y _ { n + 1 } = y _ { n } + h \left( 2 k _ { 1 } + k _ { 2 } + k _ { 3 } + 2 k _ { 4 } \right) / 6 , \text { where } k _ { 1 } = f \left( x _ { n } , y _ { n } \right) , \&#10;k _ { 2 } = f \left( x _ { n } + h / 2 , y _ { n } + h k _ { 1 } \right) , k _ { 3 } = f \left( x _ { n } + h / 2 , y _ { n } + h k _ { 2 } \right) , \&#10;k _ { 4 } = f \left( x _ { n } + h , y _ { n } + h k _ { 3 } \right)&#10;\end{array}$&#10;E) $\begin{array} { l } &#10;y _ { n + 1 } = y _ { n } + h \left( k _ { 1 } + 2 k _ { 2 } + 2 k _ { 3 } + k _ { 4 } \right) / 6 , \text { where } k _ { 1 } = f \left( x _ { n } , y _ { n } \right) , \&#10;k _ { 2 } = f \left( x _ { n } + h / 3 , y _ { n } + h k _ { 1 } / 2 \right) , k _ { 3 } = f \left( x _ { n } + 2 h / 3 , y _ { n } + h k _ { 2 } / 2 \right) , \&#10;k _ { 4 } = f \left( x _ { n } + h , y _ { n } + h k _ { 3 } \right)&#10;\end{array}$

Accepted Answer

The most popular fourth order Runge-Kutta method is described by the formula in option C, where the next value $y_{n+1}$ is calculated using a weighted average of four increments, $k_1$, $k_2$, $k_3$, and $k_4$, with specific coefficients (1, 2, 2, 1) and the increments calculated at different points within the interval using previous increments. This method is widely used due to its accuracy and efficiency for solving ordinary differential equations.

Question 5

The local truncation error for the improved Euler's method is&#10;A) $O ( h )$&#10;B) $O \left( h ^ { 2 } \right)$&#10;C) $O \left( h ^ { 3 } \right)$&#10;D) $O \left( h ^ { 4 } \right)$&#10;E) unknown

Accepted Answer

The local truncation error for the improved Euler's method, also known as Heun's method, is $O(h^3)$. This means that the error decreases cubically as the step size $h$ decreases, making it more accurate than the basic Euler's method, which has a local truncation error of $O(h^2)$.

Question 6

The standard central difference approximation of $y ^ { \prime \prime } ( x )$ is&#10;A) $( y ( x + h ) - 2 y ( x ) + y ( x - h ) ) / h ^ { 2 }$&#10;B) $( y ( x + h ) + 2 y ( x ) + y ( x - h ) ) / h ^ { 2 }$&#10;C) $( y ( x + h ) - 2 y ( x ) + y ( x - h ) ) / h$&#10;D) $( y ( x + h ) + 2 y ( x ) + y ( x - h ) ) / h$&#10;E) $( y ( x + h ) - y ( x - h ) ) / h$

Accepted Answer

The standard central difference approximation for the second derivative $y''(x)$ is given by the formula $(y(x+h) - 2y(x) + y(x-h))/h^2$, which accurately approximates the curvature or concavity of the function at point $x$ using values at $x+h$ and $x-h$.

Question 7

Using the Adams-Bashforth-Moulton method from the previous three problems, the solution of $y ^ { \prime } = y , y ( 0 ) = 1$ for $y ( 0.4 )$ with $h = 0.1$ is&#10;A) 1.5003&#10;B) 1.4978&#10;C) 1.4919&#10;D) 1.4967&#10;E) none of the above

Accepted Answer

The answer of Using the Adams-Bashforth-Moulton method from the previous...

Question 8

Using the Adams-Bashforth method from the previous problem, and using the values $y _ { 0 } = 1 , y _ { 1 } = 1.1052 , y _ { 2 } = 1.2214 , y _ { 3 } = 1.3499$ the solution $y ^ { \prime } = y , y ( 0 ) = 1$ for $y _ { n + 1 } ^ { * } = y ( 0.4 )$ with $h = 0.1$ is

A) 1.4978
B) 1.5003
C) 1.4919
D) 1.4967
E) none of the above

Accepted Answer

The answer of Using the Adams-Bashforth method from the previous...

Question 9

Using the value of $y _ { n + 1 } ^ { * }$ from the previous problem, the Adams-Moulton corrector value for the solution of $y ^ { t } = f ( x , y ) , y \left( x _ { 0 } \right) = y _ { 0 }$ is

A)

y _ { n + 1 } = y _ { n } + h \left( 9 y _ { n + 1 } ^ { \prime } - 19 y _ { n } ^ { \prime } + 5 y _ { n - 1 } ^ { \prime } + y _ { n - 2 } ^ { \prime } \right) / 24 , \text { where } y _ { n + 1 } ^ { \prime } = f \left( x _ { n + 1 } , y _ { n + 1 } ^ { * } \right)

B)

y _ { n + 1 } = y _ { n } + h \left( 9 y _ { n + 1 } ^ { \prime } + 19 y _ { n } ^ { \prime } + 5 y _ { n - 1 } ^ { \prime } + y _ { n - 2 } ^ { \prime } \right) / 34 , \text { where } y _ { n + 1 } ^ { \prime } = f \left( x _ { n + 1 } , y _ { n + 1 } ^ { * } \right)

C)

y _ { n + 1 } = y _ { n } + h \left( 9 y _ { n + 1 } ^ { \prime } + 19 y _ { n } ^ { \prime } - 5 y _ { n - 1 } ^ { \prime } - y _ { n - 2 } ^ { \prime } \right) / 24 , \text { where } y _ { n + 1 } ^ { \prime } = f \left( x _ { n + 1 } , y _ { n + 1 } ^ { * } \right)

D)

y _ { n + 1 } = y _ { n } + h \left( 9 y _ { n + 1 } ^ { \prime } + 19 y _ { n } ^ { \prime } - 5 y _ { n - 1 } ^ { \prime } + y _ { n - 2 } ^ { \prime } \right) / 24 , \text { where } y _ { n + 1 } ^ { \prime } = f \left( x _ { n + 1 } , y _ { n + 1 } ^ { * } \right)

E) none of the above

Accepted Answer

The answer of Using the value of \(y _ {...

Question 10

The Euler's method solution for $y ( 0.2 )$ of $y ^ { \prime \prime } + y = 0 , y ^ { \prime } ( 0 ) = 1$ using $h = 0.1$ is&#10;A) 0.14&#10;B) 0.2&#10;C) 0.21&#10;D) 0.11&#10;E) 0.12

Accepted Answer

The answer of The Euler's method solution for \(y (...

Question 11

The Adams-Bashforth formula for finding the solution of $y ^ { t } = f ( x , y ) , y \left( x _ { 0 } \right) = y _ { 0 }$ is&#10;A) $\begin{array} { l } &#10;y _ { n + 1 } ^ { * } = y _ { n } + h \left( 55 y _ { n } ^ { \prime } - 59 y _ { n - 1 } ^ { \prime } - 37 y _ { n - 2 } ^ { \prime } + 65 y _ { n - 3 } ^ { \prime } \right) / 24 , \text { where } y _ { n } ^ { \prime } = f \left( x _ { n } , y _ { n } \right) \&#10;y _ { n - 1 } ^ { \prime } = f \left( x _ { n - 1 } , y _ { n - 1 } \right) , y _ { n - 2 } ^ { \prime } = f \left( x _ { n - 2 } , y _ { n - 2 } \right) , y _ { n - 3 } ^ { \prime } = f \left( x _ { n - 3 } , y _ { n - 3 } \right)&#10;\end{array}$&#10;B) $\begin{array} { l } &#10;y _ { n + 1 } ^ { * } = y _ { n } + h \left( 59 y _ { n } ^ { \prime } - 55 y _ { n - 1 } ^ { \prime } + 37 y _ { n - 2 } ^ { \prime } - 17 y _ { n - 3 } ^ { \prime } \right) / 24 , \text { where } y _ { n } ^ { \prime } = f \left( x _ { n } , y _ { n } \right) \&#10;y _ { n - 1 } ^ { \prime } = f \left( x _ { n - 1 } , y _ { n - 1 } \right) , y _ { n - 2 } ^ { \prime } = f \left( x _ { n - 2 } , y _ { n - 2 } \right) , y _ { n - 3 } ^ { \prime } = f \left( x _ { n - 3 } , y _ { n - 3 } \right)&#10;\end{array}$&#10;C) $\begin{array} { l } &#10;y _ { n + 1 } ^ { * } = y _ { n } + h \left( 55 y _ { n } ^ { \prime } + 59 y _ { n - 1 } ^ { \prime } - 37 y _ { n - 2 } ^ { \prime } - 9 y _ { n - 3 } ^ { \prime } \right) / 24 , \text { where } y _ { n } ^ { \prime } = f \left( x _ { n } , y _ { n } \right) \&#10;y _ { n - 1 } ^ { \prime } = f \left( x _ { n - 1 } , y _ { n - 1 } \right) , y _ { n - 2 } ^ { \prime } = f \left( x _ { n - 2 } , y _ { n - 2 } \right) , y _ { n - 3 } ^ { \prime } = f \left( x _ { n - 3 } , y _ { n - 3 } \right)&#10;\end{array}$&#10;D) $\begin{array} { l } &#10;y _ { n + 1 } ^ { * } = y _ { n } + h \left( 55 y _ { n } ^ { \prime } - 59 y _ { n - 1 } ^ { \prime } + 37 y _ { n - 2 } ^ { \prime } - 9 y _ { n - 3 } ^ { \prime } \right) / 24 , \text { where } y _ { n } ^ { \prime } = f \left( x _ { n } , y _ { n } \right) \&#10;y _ { n - 1 } ^ { \prime } = f \left( x _ { n - 1 } , y _ { n - 1 } \right) , y _ { n - 2 } ^ { \prime } = f \left( x _ { n - 2 } , y _ { n - 2 } \right) , y _ { n - 3 } ^ { \prime } = f \left( x _ { n - 3 } , y _ { n - 3 } \right)&#10;\end{array}$&#10;E) none of the above

Accepted Answer

The answer of The Adams-Bashforth formula for finding the solution...

Question 12

Which of the following are second order Runge-Kutta methods for the solution of $y ^ { t } = f ( x , y ) , y \left( x _ { 0 } \right) = y _ { 0 }$ ? Select all that apply.&#10;A) $y _ { n + 1 } = y _ { n } + h \left( k _ { 1 } + k _ { 2 } \right) / 2 \text {, where } k _ { 1 } = f \left( x _ { n } , y _ { n } \right) , k _ { 2 } = f \left( x _ { n } + h , y _ { n } + h k _ { 1 } \right)$&#10;B) $\begin{array} { l } &#10;y _ { n + 1 } = y _ { n } + h \left( k _ { 1 } / 3 + 2 k _ { 2 } / 3 \right) , \text { where } k _ { 1 } = f \left( x _ { n } , y _ { n } \right) \&#10;k _ { 2 } = f \left( x _ { n } + 3 h / 4 , y _ { n } + 3 h k _ { 1 } / 4 \right)&#10;\end{array}$&#10;C) $\begin{array} { l } &#10;y _ { n + 1 } = y _ { n } + h \left( 2 k _ { 1 } / 3 + k _ { 2 } / 3 \right) , \text { where } k _ { 1 } = f \left( x _ { n } , y _ { n } \right) \&#10;k _ { 2 } = f \left( x _ { n } + 3 h / 2 , y _ { n } + 3 h k _ { 1 } / 2 \right)&#10;\end{array}$&#10;D) $y _ { n + 1 } = y _ { n } + h \left( k _ { 1 } + k _ { 2 } \right) / 2 \text {, where } k _ { 1 } = f \left( x _ { n } , y _ { n } \right) , k _ { 2 } = f \left( x _ { n } + 2 h , y _ { n } + 2 h k _ { 1 } \right)$&#10;E) $y _ { n + 1 } = y _ { n } + h \left( 3 k _ { 1 } + k _ { 2 } \right) / 4 \text {, where } k _ { 1 } = f \left( x _ { n } , y _ { n } \right) , k _ { 2 } = f \left( x _ { n } + 2 h , y _ { n } + 2 h k _ { 1 } \right)$

Accepted Answer

The answer of Which of the following are second order...

Question 13

The improved Euler's formula for solving $y ^ { \prime } = f ( x , y ) , y ( \bar { x } ) = \bar { y }$ is&#10;A) $y _ { n + 1 } = y _ { n } - f \left( x _ { n } , y _ { n } \right) , y _ { 0 } = \bar { y } , n = 0,1,2 , \ldots$&#10;B) $y _ { n + 1 } = y _ { n } - h f \left( x _ { n } , y _ { n } \right) , y _ { 0 } = \bar { y } , n = 0,1,2 , \ldots$&#10;C) $y _ { n + 1 } = y _ { n } + h f \left( x _ { n } , y _ { n } \right) , y _ { 0 } = \bar { y } , n = 0,1,2 , \ldots$&#10;D) $y _ { n + 1 } = y _ { n } + \left( f \left( x _ { n } , y _ { n } \right) + f \left( x _ { n + 1 } , y _ { n + 1 } ^ { * } \right) / 2 \right) , y _ { 0 } = \bar { y } , n = 0,1,2 , \ldots \text { where } y _ { n + 1 } ^ { * }$&#10;is predicted from Euler's formula&#10;E) $y _ { n + 1 } = y _ { n } + h \left( f \left( x _ { n } , y _ { n } \right) + f \left( x _ { n + 1 } , y _ { n + 1 } ^ { * } \right) / 2 \right) , y _ { 0 } = \bar { y } , n = 0,1,2 , \ldots \text { where } y _ { n + 1 } ^ { * }$&#10;is predicted from Euler's formula

Accepted Answer

The answer of The improved Euler's formula for solving \(y...

Question 14

The standard backward difference approximation of $y ^ { \prime } ( x )$ is&#10;A) $( y ( x + h ) - y ( x ) ) / h$&#10;B) $( y ( x ) - y ( x - h ) ) / h$&#10;C) $( y ( x + h ) - y ( x ) ) / h ^ { 2 }$&#10;D) $y ( x + h ) - y ( x )$&#10;E) $y ( x ) - y ( x + h )$

Accepted Answer

The answer of The standard backward difference approximation of \(y...

Question 15

The solution of $y ^ { \prime } = x + y , y ( 0 ) = 1 \text { for } y ( 0.2 )$ , using the improved Euler's method with $h = 0.1$ is&#10;A) 1.2055&#10;B) 1.21625&#10;C) 1.24205&#10;D) 1.226525&#10;E) 1.235625

Accepted Answer

The answer of The solution of \(y ^ { \prime...

Question 16

The solution of $y ^ { \prime } = x + y , y ( 0 ) = 1 \text { for } y ( 0.2 )$ , using Euler's method with $h = 0.1$ is&#10;A) 1.01&#10;B) 1.11&#10;C) 1.21&#10;D) 1.22&#10;E) 1.23

Accepted Answer

The answer of The solution of \(y ^ { \prime...

Question 17

Using the notation from the text, the finite difference equation for solving the boundary value problem $y ^ { \prime \prime } + P ( x ) y ^ { \prime } + Q ( x ) y = f ( x ) , y ( a ) = \alpha , y ( b ) = \beta$ is

A)

\left( 1 - h P _ { i } / 2 \right) y _ { i + 1 } + \left( - 2 + h ^ { 2 } Q _ { i } \right) y _ { i } + \left( 1 + h P _ { i } / 2 \right) y _ { i - 1 } = h ^ { 2 } f _ { i }

B)

\left( 1 - h P _ { i } / 2 \right) y _ { i + 1 } + \left( - 2 + h ^ { 2 } Q _ { i } \right) y _ { i } + \left( 1 - h P _ { i } / 2 \right) y _ { i - 1 } = h ^ { 2 } f _ { i }

C)

\left( 1 + h P _ { i } / 2 \right) y _ { i + 1 } + \left( - 2 + h ^ { 2 } Q _ { i } \right) y _ { i } + \left( 1 + h P _ { i } / 2 \right) y _ { i - 1 } = h ^ { 2 } f _ { i }

D)

\left( 1 + h P _ { i } / 2 \right) y _ { i + 1 } + \left( 2 - h ^ { 2 } Q _ { i } \right) y _ { i } + \left( 1 - h P _ { i } / 2 \right) y _ { i - 1 } = h ^ { 2 } f _ { i }

E)

\left( 1 + h P _ { i } / 2 \right) y _ { i + 1 } + \left( - 2 + h ^ { 2 } Q _ { i } \right) y _ { i } + \left( 1 - h P _ { i } / 2 \right) y _ { i - 1 } = h ^ { 2 } f _ { i }

Accepted Answer

The answer of Using the notation from the text, the...

Question 18

Using the method from the previous problem, the solution of $y ^ { \prime } = x + y , y ( 0 ) = 1 \text { for } y ( 0.2 )$ with $h = 0.2$ is&#10;A) 1.222&#10;B) 1.22&#10;C) 1.2213&#10;D) 1.24&#10;E) 1.21

Accepted Answer

The answer of Using the method from the previous problem,...

Question 19

Using the method from the previous problem, the solution of $y ^ { \prime } = x + y , y ( 0 ) = 1 \text { for } y ( 0.2 )$ with $h = 0.2$ is&#10;A) 1.241&#10;B) 1.242&#10;C) 1.2422&#10;D) 1.2426&#10;E) 1.2428

Accepted Answer

The answer of Using the method from the previous problem,...

Question 20

When entering the number $1 / 7$ into a three digit base ten calculator, the actual value entered is&#10;A) $1 / 7$&#10;B) $.143$&#10;C) $.142$&#10;D) $.140$&#10;E) $.150$

Accepted Answer

The answer of When entering the number $1 / 7$...

Question 21

The solution of $y ^ { \prime \prime } + x y y ^ { \prime } = 0 , y ( 0 ) = 0 , y ^ { \prime } ( 0 ) = 1$ for $y ( 0.1 )$ , using the Runge-Kutta method of order four, and using $h = 0.1$ , is

A) 0.0909
B) 0.09999
C) 0.09099
D) 0.09899
E) 0.08899

Accepted Answer

The answer of The solution of \(y ^ { \prime...

Question 22

Using the method from the previous problem, the solution of $y ^ { \prime } = y , y ( 0 ) = 1 \text { for } y ( 0.2 )$ with $h = 0.2$ is&#10;A) 1.24&#10;B) 1.241&#10;C) 1.214&#10;D) 1.2214&#10;E) 1.224

Accepted Answer

The answer of Using the method from the previous problem,...

Question 23

The Euler formula for solving the system $y ^ { t } = u , u ^ { t } = f ( x , y , u ) , y \left( x _ { 0 } \right) = y _ { 0 } , u \left( x _ { 0 } \right) = u _ { 0 }$ is&#10;A) $y _ { n + 1 } = y _ { n } + h u _ { n } , u _ { n + 1 } = u _ { n } + h f \left( x _ { n } , y _ { n } , u _ { n } \right)$&#10;B) $y _ { n + 1 } = y _ { n } - h u _ { n } , u _ { n + 1 } = u _ { n } + h f \left( x _ { n } , y _ { n } , u _ { n } \right)$&#10;C) $y _ { n + 1 } = y _ { n } + h u _ { n } , u _ { n + 1 } = u _ { n } - h f \left( x _ { n } , y _ { n } , u _ { n } \right)$&#10;D) $y _ { n + 1 } = y _ { n } + h f \left( x _ { n } , y _ { n } , u _ { n } \right) , u _ { n + 1 } = u _ { n } + h u _ { n }$&#10;E) none of the above

Accepted Answer

The answer of The Euler formula for solving the system...

Question 24

A popular second order Runge-Kutta method for the solution of $y ^ { t } = f ( x , y ) , y \left( x _ { 0 } \right) = y _ { 0 }$ is&#10;A) $\begin{array} { l } &#10;y _ { n + 1 } = y _ { n } + h \left( k _ { 1 } + k _ { 2 } \right) / 2 , \text { where } k _ { 1 } = f \left( x _ { n } , y _ { n } \right) \&#10;k _ { 2 } = f \left( x _ { n } + h / 2 , y _ { n } + h k _ { 1 } / 2 \right)&#10;\end{array}$&#10;B) $y _ { n + 1 } = y _ { n } + h \left( k _ { 1 } + k _ { 2 } \right) / 2 \text {, where } k _ { 1 } = f \left( x _ { n } , y _ { n } \right) , k _ { 2 } = f \left( x _ { n } + h , y _ { n } + h k _ { 1 } / 2 \right)$&#10;C) $y _ { n + 1 } = y _ { n } + h \left( k _ { 1 } + k _ { 2 } \right) / 2 \text {, where } k _ { 1 } = f \left( x _ { n } , y _ { n } \right) , k _ { 2 } = f \left( x _ { n } + h / 2 , y _ { n } + h k _ { 1 } \right)$&#10;D) $y _ { n + 1 } = y _ { n } + h \left( k _ { 1 } + k _ { 2 } \right) / 2 \text {, where } k _ { 1 } = f \left( x _ { n } , y _ { n } \right) , k _ { 2 } = f \left( x _ { n } + h , y _ { n } + h k _ { 1 } \right)$&#10;E) none of the above

Accepted Answer

The answer of A popular second order Runge-Kutta method for...

Question 25

The Adams-Bashforth formula for finding the solution of $y ^ { t } = f ( x , y ) , y \left( x _ { 0 } \right) = y _ { 0 }$ is&#10;A) $\begin{array} { l } &#10;y _ { n + 1 } ^ { * } = y _ { n } + h \left( 55 y _ { n } ^ { \prime } + 59 y _ { n - 1 } ^ { \prime } - 37 y _ { n - 2 } ^ { \prime } - 9 y _ { n - 3 } ^ { \prime } \right) / 24 , \text { where } y _ { n } ^ { \prime } = f \left( x _ { n } , y _ { n } \right) \&#10;y _ { n - 1 } ^ { \prime } = f \left( x _ { n - 1 } , y _ { n - 1 } \right) , y _ { n - 2 } ^ { \prime } = f \left( x _ { n - 2 } , y _ { n - 2 } \right) , y _ { n - 3 } ^ { \prime } = f \left( x _ { n - 3 } , y _ { n - 3 } \right)&#10;\end{array}$&#10;B) $\begin{array} { l } &#10;y _ { n + 1 } ^ { * } = y _ { n } + h \left( 55 y _ { n } ^ { \prime } - 59 y _ { n - 1 } ^ { \prime } + 37 y _ { n - 2 } ^ { \prime } - 9 y _ { n - 3 } ^ { \prime } \right) / 24 , \text { where } y _ { n } ^ { \prime } = f \left( x _ { n } , y _ { n } \right) \&#10;y _ { n - 1 } ^ { \prime } = f \left( x _ { n - 1 } , y _ { n - 1 } \right) , y _ { n - 2 } ^ { \prime } = f \left( x _ { n - 2 } , y _ { n - 2 } \right) , y _ { n - 3 } ^ { \prime } = f \left( x _ { n - 3 } , y _ { n - 3 } \right)&#10;\end{array}$&#10;C) $\begin{array} { l } &#10;y _ { n + 1 } ^ { * } = y _ { n } + h \left( 55 y _ { n } ^ { \prime } - 59 y _ { n - 1 } ^ { \prime } - 37 y _ { n - 2 } ^ { \prime } + 65 y _ { n - 3 } ^ { \prime } \right) / 24 , \text { where } y _ { n } ^ { \prime } = f \left( x _ { n } , y _ { n } \right) \&#10;y _ { n - 1 } ^ { \prime } = f \left( x _ { n - 1 } , y _ { n - 1 } \right) , y _ { n - 2 } ^ { \prime } = f \left( x _ { n - 2 } , y _ { n - 2 } \right) , y _ { n - 3 } ^ { \prime } = f \left( x _ { n - 3 } , y _ { n - 3 } \right)&#10;\end{array}$&#10;D) $\begin{array} { l } &#10;y _ { n + 1 } ^ { * } = y _ { n } + h \left( 59 y _ { n } ^ { \prime } - 55 y _ { n - 1 } ^ { \prime } + 37 y _ { n - 2 } ^ { \prime } - 17 y _ { n - 3 } ^ { \prime } \right) / 24 , \text { where } y _ { n } ^ { \prime } = f \left( x _ { n } , y _ { n } \right) \&#10;y _ { n - 1 } ^ { \prime } = f \left( x _ { n - 1 } , y _ { n - 1 } \right) , y _ { n - 2 } ^ { \prime } = f \left( x _ { n - 2 } , y _ { n - 2 } \right) , y _ { n - 3 } ^ { \prime } = f \left( x _ { n - 3 } , y _ { n - 3 } \right)&#10;\end{array}$&#10;E) none of the above

Accepted Answer

The answer of The Adams-Bashforth formula for finding the solution...

Question 26

Using the method from the previous two problems, using the values $y _ { 0 } = 1 , y _ { 1 } = 1.1052 , y _ { 2 } = 1.2214 , y _ { 3 } = 1.3499$ the solution of $y ^ { \prime } = y , y ( 0 ) = 1 \text { for } y ( 0.4 )$ with $h = 0.1$ is

A) 1.4919
B) 1.4967
C) 1.4978
D) 1.5003
E) none of the above

Accepted Answer

The answer of Using the method from the previous two...

Question 27

The solution of $y ^ { \prime } = y , y ( 0 ) = 1 \text { for } y ( 0.2 )$ , using the improved Euler's method with $h = 0.1$ is&#10;A) 1.22125&#10;B) 1.210625&#10;C) 1.226525&#10;D) 1.21525&#10;E) 1.221025

Accepted Answer

The answer of The solution of \(y ^ { \prime...

Question 28

When entering the number $1 / 3$ into a three digit base ten calculator, the actual value entered is&#10;A) $1 / 3$&#10;B) $.333$&#10;C) $.334$&#10;D) $.300$&#10;E) $.330$

Accepted Answer

The answer of When entering the number $1 / 3$...

Question 29

The fourth order Runge-Kutta method for solving $y ^ { \prime \prime } = f \left( x , y , y ^ { \prime } \right) , y \left( x _ { 0 } \right) = y _ { 0 } , y ^ { \prime } \left( x _ { 0 } \right) = u _ { 0 }$ is

A)

\begin{array} { l } y _ { n + 1 } = y _ { n } + h \left( m _ { 1 } - 2 m _ { 2 } + 2 m _ { 3 } - m _ { 4 } \right) / 6 , \\u _ { n + 1 } = u _ { n } + h \left( k _ { 1 } - 2 k _ { 2 } + 2 k _ { 3 } - k _ { 4 } \right) / 6\end{array}

where

m _ { 1 } = u _ { n } , k _ { 1 } = f \left( x _ { n } , y _ { n } , u _ { n } \right)

,

\begin{array} { l } m _ { 2 } = u _ { n } + h k _ { 1 } / 2 , k _ { 2 } = f \left( x _ { n } + h / 2 , y _ { n } + h m _ { 1 } / 2 , u _ { n } + h k _ { 1 } / 2 \right) \\m _ { 3 } = u _ { n } + h k _ { 2 } / 2 , k _ { 3 } = f \left( x _ { n } + h / 2 , y _ { n } + h m _ { 2 } / 2 , u _ { n } + h k _ { 2 } / 2 \right) \\m _ { 4 } = u _ { n } + h k _ { 3 } , k _ { 4 } = f \left( x _ { n } + h , y _ { n } + h m _ { 3 } , u _ { n } + h k _ { 3 } \right)\end{array}

B)

\begin{array} { l } y _ { n + 1 } = y _ { n } - h \left( m _ { 1 } + 2 m _ { 2 } + 2 m _ { 3 } + m _ { 4 } \right) / 6 , \\u _ { n + 1 } = u _ { n } - h \left( k _ { 1 } + 2 k _ { 2 } + 2 k _ { 3 } + k _ { 4 } \right) / 6\end{array}

where

m _ { 1 } = u _ { n } , k _ { 1 } = f \left( x _ { n } , y _ { n } , u _ { n } \right)

,

\begin{array} { l } m _ { 2 } = u _ { n } + h k _ { 1 } / 2 , k _ { 2 } = f \left( x _ { n } + h / 2 , y _ { n } + h m _ { 1 } / 2 , u _ { n } + h k _ { 1 } / 2 \right) \\m _ { 3 } = u _ { n } + h k _ { 2 } / 2 , k _ { 3 } = f \left( x _ { n } + h / 2 , y _ { n } + h m _ { 2 } / 2 , u _ { n } + h k _ { 2 } / 2 \right) \\m _ { 4 } = u _ { n } + h k _ { 3 } , k _ { 4 } = f \left( x _ { n } + h , y _ { n } + h m _ { 3 } , u _ { n } + h k _ { 3 } \right)\end{array}

C)

\begin{array} { l } y _ { n + 1 } = y _ { n } + h \left( m _ { 1 } + 2 m _ { 2 } + 2 m _ { 3 } + m _ { 4 } \right) / 6 , \\u _ { n + 1 } = u _ { n } - h \left( k _ { 1 } + 2 k _ { 2 } + 2 k _ { 3 } + k _ { 4 } \right) / 6\end{array}

where

m _ { 1 } = u _ { n } , k _ { 1 } = f \left( x _ { n } , y _ { n } , u _ { n } \right)

,

\begin{array} { l } m _ { 2 } = u _ { n } + h k _ { 1 } / 2 , k _ { 2 } = f \left( x _ { n } + h / 2 , y _ { n } + h m _ { 1 } / 2 , u _ { n } + h k _ { 1 } / 2 \right) \\m _ { 3 } = u _ { n } + h k _ { 2 } / 2 , k _ { 3 } = f \left( x _ { n } + h / 2 , y _ { n } + h m _ { 2 } / 2 , u _ { n } + h k _ { 2 } / 2 \right) \\m _ { 4 } = u _ { n } + h k _ { 3 } , k _ { 4 } = f \left( x _ { n } + h , y _ { n } + h m _ { 3 } , u _ { n } + h k _ { 3 } \right)\end{array}

D)

\begin{array} { l } y _ { n + 1 } = y _ { n } - h \left( m _ { 1 } + 2 m _ { 2 } + 2 m _ { 3 } + m _ { 4 } \right) / 6 , \\u _ { n + 1 } = u _ { n } + h \left( k _ { 1 } + 2 k _ { 2 } + 2 k _ { 3 } + k _ { 4 } \right) / 6\end{array}

where

m _ { 1 } = u _ { n } , k _ { 1 } = f \left( x _ { n } , y _ { n } , u _ { n } \right)

,

\begin{array} { l } m _ { 2 } = u _ { n } + h k _ { 1 } / 2 , k _ { 2 } = f \left( x _ { n } + h / 2 , y _ { n } + h m _ { 1 } / 2 , u _ { n } + h k _ { 1 } / 2 \right) \\m _ { 3 } = u _ { n } + h k _ { 2 } / 2 , k _ { 3 } = f \left( x _ { n } + h / 2 , y _ { n } + h m _ { 2 } / 2 , u _ { n } + h k _ { 2 } / 2 \right) \\m _ { 4 } = u _ { n } + h k _ { 3 } , k _ { 4 } = f \left( x _ { n } + h , y _ { n } + h m _ { 3 } , u _ { n } + h k _ { 3 } \right)\end{array}

E)

\begin{array} { l } y _ { n + 1 } = y _ { n } + h \left( m _ { 1 } + 2 m _ { 2 } + 2 m _ { 3 } + m _ { 4 } \right) / 6 , \\u _ { n + 1 } = u _ { n } + h \left( k _ { 1 } + 2 k _ { 2 } + 2 k _ { 3 } + k _ { 4 } \right) / 6\end{array}

where

m _ { 1 } = u _ { n } , k _ { 1 } = f \left( x _ { n } , y _ { n } , u _ { n } \right)

,

\begin{array} { l } m _ { 2 } = u _ { n } + h k _ { 1 } / 2 , k _ { 2 } = f \left( x _ { n } + h / 2 , y _ { n } + h m _ { 1 } / 2 , u _ { n } + h k _ { 1 } / 2 \right) \\m _ { 3 } = u _ { n } + h k _ { 2 } / 2 , k _ { 3 } = f \left( x _ { n } + h / 2 , y _ { n } + h m _ { 2 } / 2 , u _ { n } + h k _ { 2 } / 2 \right) \\m _ { 4 } = u _ { n } + h k _ { 3 } , k _ { 4 } = f \left( x _ { n } + h , y _ { n } + h m _ { 3 } , u _ { n } + h k _ { 3 } \right)\end{array}

Accepted Answer

The answer of The fourth order Runge-Kutta method for solving...

Question 30

The problem $y ^ { \prime \prime } + x y y ^ { \prime } = 0 , y ( 0 ) = 0 , y ^ { \prime } ( 0 ) = 1$ can be written as a system of two equations as follows.&#10;A) $y ^ { \prime } = u , u ^ { \prime } = x y u , y ( 0 ) = 0 , u ( 0 ) = 0$&#10;B) $y ^ { \prime } = u , u ^ { \prime } = - x y u , y ( 0 ) = 1 , u ( 0 ) = 0$&#10;C) $y ^ { \prime } = u , u ^ { \prime } = x y u , y ( 0 ) = 1 , u ( 0 ) = 0$&#10;D) $y ^ { \prime } = u , u ^ { \prime } = x y u , y ( 0 ) = 0 , u ( 0 ) = 1$&#10;E) $y ^ { \prime } = u , u ^ { \prime } = - x y u , y ( 0 ) = 0 , u ( 0 ) = 1$

Accepted Answer

The answer of The problem \(y ^ { \prime \prime...

Question 31

Using the value of $y _ { n + 1 } ^ { * }$ from the previous problem, the Adams-Moulton corrector value for the solution of $y ^ { t } = f ( x , y ) , y \left( x _ { 0 } \right) = y _ { 0 }$ is

A)

y _ { n + 1 } = y _ { n } + h \left( 9 y _ { n + 1 } ^ { \prime } - 19 y _ { n } ^ { \prime } + 5 y _ { n - 1 } ^ { \prime } + y _ { n - 2 } ^ { \prime } \right) / 24 , \text { where } y _ { n + 1 } ^ { \prime } = f \left( x _ { n + 1 } , y _ { n + 1 } ^ { * } \right)

B)

y _ { n + 1 } = y _ { n } + h \left( 9 y _ { n + 1 } ^ { \prime } + 19 y _ { n } ^ { \prime } + 5 y _ { n - 1 } ^ { \prime } + y _ { n - 2 } ^ { \prime } \right) / 34 , \text { where } y _ { n + 1 } ^ { \prime } = f \left( x _ { n + 1 } , y _ { n + 1 } ^ { * } \right)

C)

y _ { n + 1 } = y _ { n } + h \left( 9 y _ { n + 1 } ^ { \prime } + 19 y _ { n } ^ { \prime } - 5 y _ { n - 1 } ^ { \prime } - y _ { n - 2 } ^ { \prime } \right) / 24 , \text { where } y _ { n + 1 } ^ { \prime } = f \left( x _ { n + 1 } , y _ { n + 1 } ^ { * } \right)

D)

y _ { n + 1 } = y _ { n } + h \left( 9 y _ { n + 1 } ^ { \prime } + 19 y _ { n } ^ { \prime } - 5 y _ { n - 1 } ^ { \prime } + y _ { n - 2 } ^ { \prime } \right) / 24 , \text { where } y _ { n + 1 } ^ { \prime } = f \left( x _ { n + 1 } , y _ { n + 1 } ^ { * } \right)

E) none of the above

Accepted Answer

The answer of Using the value of \(y _ {...

Question 32

In the previous problem, the local truncation error in $y _ { n + 1 }$ is&#10;A) $0.005 e ^ { c } \text {, where } x _ { n - 1 } < c < x _ { n }$&#10;B) $0.05 e ^ { c } \text {, where } x _ { n - 1 } < c < x _ { n }$&#10;C) $0.005 e ^ { c } \text {, where } x _ { n } < c < x _ { n + 1 }$&#10;D) $0.05 e ^ { c } \text {, where } x _ { n } < c < x _ { n + 1 }$&#10;E) unknown

Accepted Answer

The answer of In the previous problem, the local truncation...

Question 33

Euler's formula for solving $y ^ { \prime } = f ( x , y ) , y ( \bar { x } ) = \bar { y }$ is&#10;A) $y _ { n + 1 } = y _ { n } - f \left( x _ { n } , y _ { n } \right) , y _ { 0 } = \bar { y } , n = 0,1,2 , \ldots$&#10;B) $y _ { n + 1 } = y _ { n } - h f \left( x _ { n } , y _ { n } \right) , y _ { 0 } = \bar { y } , n = 0,1,2 , \ldots$&#10;C) $y _ { n + 1 } = y _ { n } + h f \left( x _ { n } , y _ { n } \right) , y _ { 0 } = \bar { y } , n = 0,1,2 , \ldots$&#10;D) $y _ { n + 1 } = y _ { n } + h \left( f \left( x _ { n } , y _ { n } \right) + f \left( x _ { n + 1 } , y _ { n + 1 } ^ { * } \right) / 2 \right) , y _ { 0 } = \bar { y } , n = 0,1,2 , \ldots \text { where } y _ { n + 1 } ^ { * }$&#10;is predicted from Euler's formula&#10;E) $y _ { n + 1 } = y _ { n } + \left( f \left( x _ { n } , y _ { n } \right) + f \left( x _ { n + 1 } , y _ { n + 1 } ^ { * } \right) / 2 \right) , y _ { 0 } = \bar { y } , n = 0,1,2 , \ldots \text { where } y _ { n + 1 } ^ { * }$&#10;is predicted from Euler's formula

Accepted Answer

The answer of Euler's formula for solving \(y ^ {...

Question 34

When entering the number $1 / 3$ into a three digit base ten calculator, the round-off error is&#10;A) $1 / 30$&#10;B) $1 / 300$&#10;C) $1 / 3000$&#10;D) $0.003$&#10;E) $0.0003$

Accepted Answer

The answer of When entering the number $1 / 3$...

Question 35

Euler's method is what type of Runge-Kutta method?&#10;A) first order&#10;B) second order&#10;C) third order&#10;D) fourth order&#10;E) It is not a Runge-Kutta method

Accepted Answer

The answer of Euler's method is what type of Runge-Kutta...

Question 36

The most popular fourth order Runge-Kutta method for the solution of $y ^ { t } = f ( x , y ) , y \left( x _ { 0 } \right) = y _ { 0 }$ is&#10;A) $\begin{array} { l } &#10;y _ { n + 1 } = y _ { n } + h \left( k _ { 1 } + 2 k _ { 2 } + 2 k _ { 3 } + k _ { 4 } \right) / 6 , \text { where } k _ { 1 } = f \left( x _ { n } , y _ { n } \right) , \&#10;k _ { 2 } = f \left( x _ { n } + h / 2 , y _ { n } + h k _ { 1 } / 2 \right) , k _ { 3 } = f \left( x _ { n } + h / 2 , y _ { n } + h k _ { 2 } / 2 \right) , \&#10;k _ { 4 } = f \left( x _ { n } + h , y _ { n } + h k _ { 3 } \right)&#10;\end{array}$&#10;B) $\begin{array} { l } &#10;y _ { n + 1 } = y _ { n } + h \left( 2 k _ { 1 } + k _ { 2 } + k _ { 3 } + 2 k _ { 4 } \right) / 6 , \text { where } k _ { 1 } = f \left( x _ { n } , y _ { n } \right) , \&#10;k _ { 2 } = f \left( x _ { n } + h / 2 , y _ { n } + h k _ { 1 } \right) , k _ { 3 } = f \left( x _ { n } + h / 2 , y _ { n } + h k _ { 2 } \right) , \&#10;k _ { 4 } = f \left( x _ { n } + h , y _ { n } + h k _ { 3 } \right)&#10;\end{array}$&#10;C) $\begin{array} { l } &#10;y _ { n + 1 } = y _ { n } + h \left( k _ { 1 } + 2 k _ { 2 } + 2 k _ { 3 } + k _ { 4 } \right) / 6 , \text { where } k _ { 1 } = f \left( x _ { n } , y _ { n } \right) , \&#10;k _ { 2 } = f \left( x _ { n } + h / 3 , y _ { n } + h k _ { 1 } / 2 \right) , k _ { 3 } = f \left( x _ { n } + 2 h / 3 , y _ { n } + h k _ { 2 } / 2 \right) , \&#10;k _ { 4 } = f \left( x _ { n } + h , y _ { n } + h k _ { 3 } \right)&#10;\end{array}$&#10;D) $\begin{array} { l } &#10;y _ { n + 1 } = y _ { n } + h \left( 2 k _ { 1 } + 2 k _ { 2 } + 2 k _ { 3 } + 2 k _ { 4 } \right) / 6 , \text { where } k _ { 1 } = f \left( x _ { n } , y _ { n } \right) , \&#10;k _ { 2 } = f \left( x _ { n } + h / 2 , y _ { n } + h k _ { 1 } / 2 \right) , k _ { 3 } = f \left( x _ { n } + h / 2 , y _ { n } + h k _ { 2 } / 2 \right) , \&#10;k _ { 4 } = f \left( x _ { n } + h , y _ { n } + h k _ { 3 } \right)&#10;\end{array}$&#10;E) $\begin{array} { l } &#10;y _ { n + 1 } = y _ { n } + h \left( k _ { 1 } + 2 k _ { 2 } + 2 k _ { 3 } + k _ { 4 } \right) / 6 , \text { where } k _ { 1 } = f \left( x _ { n } , y _ { n } \right) , \&#10;k _ { 2 } = f \left( x _ { n } + h / 2 , y _ { n } + h k _ { 1 } \right) , k _ { 3 } = f \left( x _ { n } + h / 2 , y _ { n } + h k _ { 2 } \right) , \&#10;k _ { 4 } = f \left( x _ { n } + h , y _ { n } + h k _ { 3 } \right)&#10;\end{array}$

Accepted Answer

The answer of The most popular fourth order Runge-Kutta method...

Question 37

The solution of $y ^ { \prime } = y , y ( 0 ) = 1 \text { for } y ( 0.2 )$ , using Euler's method with $h = 0.1$ is&#10;A) 1.01&#10;B) 1.1&#10;C) 1.11&#10;D) 1.21&#10;E) 1.22

Accepted Answer

The answer of The solution of \(y ^ { \prime...

Question 38

Using the method from the previous problem, the solution of $y ^ { \prime } = y , y ( 0 ) = 1 \text { for } y ( 0.2 )$ with $h = 0.2$ is&#10;A) 1.2&#10;B) 1.21&#10;C) 1.214&#10;D) 1.22&#10;E) 1.24

Accepted Answer

The answer of Using the method from the previous problem,...

Question 39

Using Euler's method on the previous problem and using a value of $h = 0.1$ , the solution for $y ( 0.2 )$ is&#10;A) 0.11&#10;B) 0.2&#10;C) 0.21&#10;D) 0.22&#10;E) 0.221

Accepted Answer

The answer of Using Euler's method on the previous problem...

Question 40

The local truncation error for the improved Euler's method is&#10;A) unknown&#10;B) $O ( h )$&#10;C) $O \left( h ^ { 2 } \right)$&#10;D) $O \left( h ^ { 3 } \right)$&#10;E) $O \left( h ^ { 4 } \right)$

Accepted Answer

The answer of The local truncation error for the improved...

Deck 9: Numerical Solutions of Ordinary Differential Equations