# See the attached file for questioins

1:

Problem 2:

Find the antiderivative

Problem 3:

Find the surface area when the line segment A in the figure below is rotated about the lines:

(a) y = 1

(b) x = -2

(a) The line segment follows the function f (x) = x + 1. The integral for the surface area of revolution is:

(a) The line segment follows the function f (y) = y – 1. The integral for the surface area of revolution is:

Problem 4:

A sphere of radius 2 foot is filled with 2000 pounds of liquid. How much work is done pumping the liquid to a point 5 feet above the top of the sphere?

Problem 5:

Find the integral

Problem 6:

Find the integral

Problem 7:

Use the definition of an improper integral to evaluate the given integral:

Problem 8:

Find the indefinite integrals and evaluate the definite integrals. A particular change of variable is suggested.

Problem 9:

Evaluate the integral

Problem 10:

Evaluate the integral

Problem 11:

Evaluate the integral

Problem 12:

Show that if m and n are integers, then . (Consider m = n and

m ≠ n.)

Problem 13:

Use derivatives to determine whether the sequence below is monotonic increasing, monotonic decreasing, or neither:

Problem 14:

Each special washing of a pair of overalls removes 80% of the radioactive particles attached to the overalls. Represent, as a sequence of numbers, the percent of the original radioactive particles that remain after each washing.

Problem 15:

Calculate the value of the partial sum for n = 4 and n = 5, and find a formula for sn. (The patterns may be more obvious if you do not simplify each term.)

Problem 16:

In the proof of the Integral Test, we derived an inequality bounding the values of the partial sums between the values of two integrals:

Problem 17:

Use any of the methods learned from this MATH141 class to determine whether the given series converge or diverge. Give reasons for your answers.

Problem 18:

Determine whether the given series Converge Absolutely, Converge Conditionally, or Diverge, and give reasons for your conclusions.

Problem 19:

Find the interval of convergence for the series below. For x in the interval of convergence, find the sum of the series as a function of x. (Hint: You know how to find the sum of a geometric series.)

Problem 20:

Represent the integral as a numerical series:

Use the series representation of these functions to calculate the limits.

Determine how many terms of the Taylor series for f(x) are needed to approximate f to within the specified error on the given interval. (For each function use the center c = 0.)

within 0.001 on [-1, 4].