Deck 6: Additional Topics in Integration

Evaluate $\int x e ^ { x / 8 } d x$ .

Use integration by parts to evaluate the integral $\int ( 3 - x ) e ^ { x } d x$ .

Evaluate $\int ( 2 - 3 x ) e ^ { - 2 x } d x$ .

Evaluate $\int ( x - 3 ) \ln ( 2 x ) d x$ .

$\int x \ln ( x + 2 ) d x = \left( \frac { x ^ { 2 } } { 2 } - 2 \right) \ln ( x + 2 ) - \frac { x ^ { 2 } } { 4 } + x + C$

Evaluate $\int x ( x - 2 ) ^ { 9 } d x$ .

Evaluate $\int x ^ { 3 } \left( x ^ { 2 } - 3 \right) ^ { 7 } d x$ .

Evaluate $\int x ( x + 7 ) ^ { 8 } d x$ .

Evaluate $\int x ^ { 7 } \left( x ^ { 4 } - 6 \right) ^ { 7 } d x$ .

Evaluate $\int x ( x + 2 ) ^ { 7 } d x$ .

Evaluate $\int x ^ { 7 } \left( x ^ { 4 } - 10 \right) ^ { 7 } d x$ .

Use integration by parts to evaluate the integral $\int \frac { x } { \sqrt { x + 8 } } d x$ .

Evaluate $\int x \ln \sqrt { x } d x$ .

Evaluate $\int x ^ { 2 } \ln x d x$ .

Evaluate $\int \frac { \ln 3 x } { x ^ { 2 } } d x$ .

Evaluate $\int \frac { \ln 9 x } { x ^ { 5 } } d x$ .

Evaluate $\int x ( \ln x ) ^ { 2 } d x$ .

Evaluate $\int x ^ { 2 } ( \ln x ) ^ { 2 } d x$ .

Evaluate $\int x ^ { 3 } e ^ { x ^ { 2 } } d x$ .

Evaluate $\int x ^ { 7 } e ^ { x ^ { 4 } } d x$ .

Evaluate $\int \frac { x } { 2 x + 5 } d x$ .

Evaluate $\int \frac { x } { 5 x + 2 } d x$ .

Use the formula $\int ( \ln x ) ^ { n } d x = x ( \ln x ) ^ { n } - n \int ( \ln x ) ^ { n - 1 } d x$ to evaluate $\int ( \ln x ) ^ { 3 } d x$ .

$\int ( \ln x ) ^ { 2 } d x = x ( \ln x ) ^ { 2 } - 2 x \ln x + 2 x + C$

After t hours on the job, a factory worker can produce $130 t e ^ { - 0.5 t }$ units per hour. How many units does the worker produce during the first 4 hours? Round to two decimal places.

If, after t hours on the job, a factory worker can produce $10 t e ^ { - 0.02 t }$ units per hour, then the worker produces 130 units during the first 5 hours.

It is projected that t years from now the population of a city will be changing at the rate of $t ^ { 2 } e ^ { 0.01 t }$ thousand people per year. If the current population is 1 million, what will the population be 4 years from now?

Given an initial population, $P _ { 0 } = 14,000$ , a renewal rate, R = 100, and a survival function, $S ( t ) = t e ^ { - 0.2 t }$ , with time t measured in years, determine the population at the end of 11 years. Round to two decimal places.

From time t = 0 to t = 5 an object's speed is given by the function $s ( t ) = t e ^ { 3 t }$ . Compute the distance travelled by the object during this time interval. Round your answer to two decimals.

An object moving in a straight line has velocity $v ( t ) = t e ^ { - \sqrt { t } }$ meters per second. Is it true that in the first 4 seconds the object will have travelled $4 e ^ { 2 } + 12$ meters?

After t seconds, an object is moving at the speed of $t e ^ { 1 - t }$ meters per second. If the object begins at 0 when t = 0, then the distance the object travels as a function of time is expressed $s ( t ) = - e ^ { 1 - t } ( t + 1 )$ .

Approximate the integral $\int _ { 1 } ^ { 2 } e ^ { 1 / x } d x$ using (a) the trapezoidal rule and (b) Simpson's rule, both with 6 subintervals. Round your answer to five decimal places.

Approximate the integral $\int _ { 0 } ^ { 1 } e ^ { x ^ { 2 } } d x$ using (a) the trapezoidal rule and (b) Simpson's rule, both with 4 subintervals. Round your answer to five decimal places.

Determine how many subintervals are required to guarantee accuracy to within 0.00001 for the approximation of the integral $$\int _ { 1 } ^ { 2 } \ln \left( 1 + x ^ { 2 } \right) d x$$ using (a) the trapezoidal rule and (b) Simpson's rule.

Assume a 6-year franchise is expected to generate profit at the rate of $\sqrt [ 3 ] { t ^ { 2 } + 13,000 }$ dollars per year. If, over the next 6 years, the prevailing annual interest rate remains fixed at 6%, compounded continuously, what is the present value of the franchise? Use Simpson's rule with n = 6 to approximate the integral. Round your answer to two decimal places.

Shortly after leaving on a road trip, two math majors realize that the car's odometer is broken. To estimate the distance they travel between 8 PM and 9 PM, they record speedometer readings every 10 minutes: $$\begin{array} { c | c | c | c | c | c | c | c | } \text { Time } & 8 : 00 & 8 : 10 & 8 : 20 & 8 : 30 & 8 : 40 & 8 : 50 & 9 : 00 \\\hline \text { Speed (mph) } & 55 & 69 & 47 & 69 & 39 & 78 & 50\end{array}$$
Using Simpson's rule and only the information in the table, get the best possible estimate of the distance they traveled between 8 PM and 9 PM. Round your answer to one decimal place.

Evaluate $\int _ { 1 } ^ { \infty } \frac { d x } { \sqrt [ 3 ] { x } }$ .

Evaluate $\int _ { 1 } ^ { \infty } \frac { 1 } { \sqrt [ 4 ] { x } } d x$

Evaluate $$\int _ { 5} ^ { \infty } \frac { 1 } { x ^ { 2 } - x } d x$$ . $$\left( \text { Hint: } \frac { 1 } { x ^ { 2 } - x } = \frac { 1 } { x - 1 } - \frac { 1 } { x } \right)$$

Evaluate $\int _ { 2 } ^ { \infty } \frac { d x } { \sqrt [ 3 ] { x ( x - 1 ) } }$ .

Evaluate $\int _ { 1 } ^ { \infty } e ^ { - 5 x } d x$ .

Given that $\int _ { 0 } ^ { \infty } e ^ { - x ^ { 2 } } d x = \frac { \sqrt { \pi } } { 2 }$ , evaluate $\int _ { 0 } ^ { \infty } e ^ { - 9 x ^ { 2 } } d x$ .

Evaluate $\int _ { 1 } ^ { \infty } e ^ { - 7 x } d x$ .

$\int _ { 0 } ^ { \infty } \frac { 1 } { ( 1 + x ) ^ { 3 } } d x = \frac { 1 } { 8 }$ .

Evaluate the improper integral: $\int _ { 2 } ^ { \infty } \frac { x ^ { 2 } } { \left( x ^ { 3 } + 6 \right) ^ { 2 } } d x$

$\int _ { 0 } ^ { \infty } \frac { 2 x } { 1 + x ^ { 2 } } d x = 0$

Evaluate $\int _ { 2 } ^ { \infty } \frac { 1 } { x ( \ln x ) ^ { 3 } } d x$ .

Evaluate $\int _ { 2 } ^ { \infty } \frac { 1 } { x \ln \sqrt { x } } d x$ .

Evaluate the improper integral: $\int _ { 0 } ^ { \infty } \frac { 1 } { ( x - 7 ) \ln ( x - 7 ) } d x$ Round your answer to two decimal places, if necessary.

Evaluate the improper integral: $\int _ { 0 } ^ { \infty } x ^ { 5 } e ^ { - x ^ { 5 } / 6 } d x$ Round to two decimal places, if necessary.

$\int _ { 0 } ^ { \infty } \frac { x ^ { 2 } } { e ^ { x ^ { 3 } } } d x = \frac { 1 } { 3 }$

$\int _ { 0 } ^ { \infty } \frac { x ^ { 4 } } { e ^ { x ^ { 5 } } } d x = \frac { 1 } { 5 }$

The long run capitalized cost of an asset that initially cost $C _ { 0 }$ dollars is given by $C = C _ { 0 } + \int _ { 0 } ^ { \infty } A ( t ) e ^ { - r t } d t$ where A(t) is the annual cost of maintenance and r is the annual rate of interest, compounded continuously. Find the long run capitalized cost, in dollars, in the case where $C _ { 0 } = \$ 5,000,000$ , A(t) = 5, 000(1 + 3t), and r = 0.08.

A hospital patient receives 4 units of a certain drug per hour intravenously. The drug is eliminated exponentially, so that the fraction that remains in the patients body for t hours is $f ( t ) = e ^ { - t / 12 }$ . If treatment is continued indefinitely, approximately how many units of the drug will be in the patient's body in the long run?

A hospital patient receives intravenously 6 units of a certain drug per hour. The drug is eliminated exponentially, so that the fraction that remains in the patients body for t hours is $f ( t ) = e ^ { - t / 11 }$ . If the treatment is continued indefinitely, approximately how many units of the drug will be in the patient's body in the long run? Round to two decimal places, if necessary.

A certain nuclear power plant produces radioactive waste at the rate of 500 pounds per year. The waste decays exponentially at the rate of 1.5% per year. How many pounds of radioactive waste from the plant will be present in the long run? Round to two decimal places, if necessary.

$f ( x ) = \left\{ \begin{array} { l l } 7 e ^ { - 7 x } & \text { for } x \geq 0 \\0 & \text { for } x < 0\end{array} \right.$ is a probability density function.

$f ( x ) = \left\{ \begin{array} { l l } \frac { 1 } { 16 } \sqrt { x } & \text { for } 0 \leq x \leq 8 \\0 & \text { otherwise }\end{array} \right.$ is a probability density function.

Find k so that $f ( x ) = \left\{ \begin{array} { l } k x ^ { 4 } + 0.4 \text { for } 0 \leq x \leq 1 \\0 \quad \text { otherw ise }\end{array} \right.$ is a probability density function.

$f ( x ) = \left\{ \begin{array} { l r } \frac { 1 } { 7 } & \text { for } 0 \leq x \leq 7 \\0 & \text { otherwise }\end{array} \right.$ is a probability density function for a particular random variable X. Use integration to find $P ( 0 \leq x \leq 3 )$ rounded to the nearest hundredth.

$f ( x ) = \left\{ \begin{array} { l l } \frac { 5 } { x ^ { 6 } } & \text { if } x \geq 1 \\0 & \text { if } x < 1\end{array} \right.$ is a probability density function for a particular random variable X. Use integration to find $P ( X \geq 3 )$

$f ( x ) = \left\{ \begin{array} { l l } \frac { 1 } { 2 } e ^ { - x / 2 } & \text { if } x \geq 0 \\0 & \text { if } x < 0\end{array} \right.$ is a probability density function for a particular random variable X. Use integration to find $P ( X \geq 4 )$

The life span of car stereos manufactured by a certain company is measured by a random variable X that is exponentially distributed with a probability density function $$f ( x ) = \left\{ \begin{array} { l l } 0.2 e ^ { - 0.2 x } & \text { if } x \geq 0 \\0 & \text { if } x < 0\end{array} \right.$$ where x is the life span in years of a randomly selected stereo. What is the probability that the life span of a randomly selected stereo is between 5 and 16 years? Round to the nearest hundredth.

The useful life X of a particular kind of machine is a random variable with density function $$f ( x ) = \left\{ \begin{array} { l l } \frac { 4 } { 15 } + \frac { 2 } { 3 x ^ { 2 } } & \text { if } 2 \leq x \leq 5 \\0 & \text { otherwise }\end{array} \right.$$ where x is the number of years a randomly selected machine stays in use. $$P ( X \leq 3 ) = \frac { 28 } { 45 }$$

The clothes dryers at a laundromat run for 45 minutes. You arrive at the laundromat and find that all of the dryers are being used. Use an appropriate uniform density function to find the probability that a dryer chosen at random will finish its cycle within 5 minutes.

Let X be a random variable that measures the age of a randomly selected virus in a particular population. Suppose X is exponentially distributed with a probability density function $$f ( x ) = \left\{ \begin{array} { l l } k e ^ { - k x } & \text { for } x \geq 0 \\0 & \text { otherw ise }\end{array} \right.$$ where x is the age of a randomly selected virus and k is a positive constant. Experiments indicate that it is four times as likely for a virus to be less than 2 days old as it is for it to be more than 2 days old. Use this information to determine k.

Suppose the length of time, x, that it takes a chimpanzee to solve a simple puzzle is measured by a random variable X that is exponentially distributed with a probability density function $$f ( x ) = \left\{ \begin{array} { l l } \frac { 2 } { 3 } e ^ { - 2 x / 3 } & \text { if } x \geq 0 \\0 & \text { if } x < 0\end{array} \right.$$ where x is in minutes. Find the probability that a randomly chosen chimpanzee will take more than 12 minutes to solve the puzzle.

Suppose the length of time that it takes a person to complete a hedgerow maze is measured by a random variable X that is exponentially distributed with a probability density function $$f ( x ) = \left\{ \begin{array} { l l } \frac { 1 } { 4 } x e ^ { - x / 2 } & \text { if } x \geq 0 \\0 & \text { if } x < 0\end{array} \right.$$ where x is the number of minutes a randomly selected person takes to complete the maze. Find the probability that a randomly chosen person will take less than 4 minutes to complete the maze.

Evaluate $\int x e ^ { x / 6 } d x$ .

Use integration by parts to evaluate the integral $\int ( 2 - x ) e ^ { x } d x$ .

Evaluate $\int x ( x + 7 ) ^ { 8 } d x$ .

Use integration by parts to evaluate the integral $\int \frac { x } { \sqrt { x + 11 } } d x$ .

Evaluate $\int x ^ { 2 } \ln x d x$ .

After t hours on the job, a factory worker can produce $130 t e ^ { - 0.5 t }$ units per hour. How many units does the worker produce during the first 4 hours? Round to two decimal places.

Given an initial population, $P _ { 0 } = 17,000$ , a renewal rate, R = 150, and a survival function, $S ( t ) = t e ^ { - 0.2 t }$ , with time t measured in years, determine the population at the end of 11 years. Round to two decimal places.

From time t = 0 to t = 2 an object's speed is given by the function $s ( t ) = t e ^ { 4 t }$ . Compute the distance travelled by the object during this time interval. Round your answer to two decimals.

Assume a 7-year franchise is expected to generate profit at the rate of $\sqrt [ 3 ] { t ^ { 2 } + 18,000 }$ dollars per year. If, over the next 7 years, the prevailing annual interest rate remains fixed at 8%, compounded continuously, what is the present value of the franchise? Use Simpson's rule with n = 6 to approximate the integral. Round your answer to two decimal places.