Difference between revisions of "022 Sample Final A"
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<span class="exam"> A dairy farmer plans to enclose a rectangular pasture adjacent to a river. To provide enough grass for the her, the pasure must contain 200 square meters of grass. No fencing is required along the river. What dimensions will use the smallest amount of fencing? | <span class="exam"> A dairy farmer plans to enclose a rectangular pasture adjacent to a river. To provide enough grass for the her, the pasure must contain 200 square meters of grass. No fencing is required along the river. What dimensions will use the smallest amount of fencing? | ||
| − | == [[ | + | == [[022_Sample Final A,_Problem_3|<span class="biglink"><span style="font-size:80%"> Problem 3 </span>]] == |
<span class="exam"> Find the antiderivative: <math>\int \frac{6}{x^2 - x - 12}</math> | <span class="exam"> Find the antiderivative: <math>\int \frac{6}{x^2 - x - 12}</math> | ||
| − | == [[ | + | == [[022_Sample Final A,_Problem_4|<span class="biglink"><span style="font-size:80%"> Problem 4 </span>]] == |
<span class="exam"> Use implicit differentiation to find <math>\frac{dy}{dx}: \qquad x+y = x^3y^3</math> | <span class="exam"> Use implicit differentiation to find <math>\frac{dy}{dx}: \qquad x+y = x^3y^3</math> | ||
| − | == [[ | + | == [[022_Sample Final A,_Problem_5|<span class="biglink"><span style="font-size:80%"> Problem 5 </span>]] == |
<span class="exam"> Find producer and consumer surpluses for the following situation: | <span class="exam"> Find producer and consumer surpluses for the following situation: | ||
<math>\text{Supply curve: }\qquad p = 18 + 3x^2 \qquad \text{Demand curve: }\qquad p = 150 - 4x</math> | <math>\text{Supply curve: }\qquad p = 18 + 3x^2 \qquad \text{Demand curve: }\qquad p = 150 - 4x</math> | ||
| − | == [[ | + | == [[022_Sample_Final_A,_Problem_6|<span class="biglink"><span style="font-size:80%"> Problem 6 </span>]] == |
<span class="exam"> Sketch the curve, including all relative exterma and points of inflection. <math>y = 3x^4 - 4x^3</math> | <span class="exam"> Sketch the curve, including all relative exterma and points of inflection. <math>y = 3x^4 - 4x^3</math> | ||
| − | == [[ | + | == [[022_Sample_Final_A,_Problem_7|<span class="biglink"><span style="font-size:80%"> Problem 7 </span>]] == |
<span class="exam">Find the present value of the income stream <math>Y = 20 + 30x</math> from now until 5 years from now, given an interest rate <math>r = 10%.</math> (note that once you plug in the limits of integration, you are finished- you do not need to simplify our answer beyond that step). | <span class="exam">Find the present value of the income stream <math>Y = 20 + 30x</math> from now until 5 years from now, given an interest rate <math>r = 10%.</math> (note that once you plug in the limits of integration, you are finished- you do not need to simplify our answer beyond that step). | ||
| − | == [[ | + | == [[022_Sample_Final_A,_Problem_8|<span class="biglink"><span style="font-size:80%"> Problem 8 </span>]] == |
<span class="exam"> | <span class="exam"> | ||
Find ther marginial productivity of labor and marginal productivity of capital for the following Cobb-Douglas productio function: (note: you must simplify so your solution does not contain negative exponents) | Find ther marginial productivity of labor and marginal productivity of capital for the following Cobb-Douglas productio function: (note: you must simplify so your solution does not contain negative exponents) | ||
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<math>f(k, l) = 200k^{0.6}l^{0.4}</math> | <math>f(k, l) = 200k^{0.6}l^{0.4}</math> | ||
| − | == [[ | + | == [[022_Sample_Final_A,_Problem_9|<span class="biglink"><span style="font-size:80%"> Problem 9 </span>]] == |
<span class="exam"> Given demand <math>p = 116 - 3x</math> , and cost <math>C = x^2 + 20x + 64</math> , find: | <span class="exam"> Given demand <math>p = 116 - 3x</math> , and cost <math>C = x^2 + 20x + 64</math> , find: | ||
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::<span class="exam">c) Maximum profit (find the x-value and the profit itself) | ::<span class="exam">c) Maximum profit (find the x-value and the profit itself) | ||
| − | == [[ | + | == [[022_Sample_Final_A,_Problem_10|<span class="biglink"><span style="font-size:80%"> Problem 10 </span>]] == |
<span class="exam">Set up the formula to find the amount of money one would have at the end of 8 years if she invests $2100 in an account paying 6% annual interest, compounded quarterly. | <span class="exam">Set up the formula to find the amount of money one would have at the end of 8 years if she invests $2100 in an account paying 6% annual interest, compounded quarterly. | ||
| − | == [[ | + | == [[022_Sample_Final_A,_Problem_11|<span class="biglink"><span style="font-size:80%"> Problem 11 </span>]] == |
<span class="exam">Find the derivative: <math>g(x) = \frac{ln(x^3 + 7)}{(x^4 + 2x^2)}</math> (note: you do not need to simplify the derivative after finding it) | <span class="exam">Find the derivative: <math>g(x) = \frac{ln(x^3 + 7)}{(x^4 + 2x^2)}</math> (note: you do not need to simplify the derivative after finding it) | ||
| − | == [[ | + | == [[022_Sample_Final_A,_Problem_12|<span class="biglink"><span style="font-size:80%"> Problem 12 </span>]] == |
<span class="exam"> Find the antiderivative: <math>\int x^2e^{3x^3}dx</math> | <span class="exam"> Find the antiderivative: <math>\int x^2e^{3x^3}dx</math> | ||
| − | == [[ | + | == [[022_Sample_Final_A,_Problem_13|<span class="biglink"><span style="font-size:80%"> Problem 13 </span>]] == |
<span class="exam">Use differentials to find <math>dy</math> given <math>y = x^2 - 6x, ~ x = 4, ~dx = -0.5</math> | <span class="exam">Use differentials to find <math>dy</math> given <math>y = x^2 - 6x, ~ x = 4, ~dx = -0.5</math> | ||
| − | == [[ | + | == [[022_Sample_Final_A,_Problem_14|<span class="biglink"><span style="font-size:80%"> Problem 14 </span>]] == |
<span class="exam"> Find all vertical and horizontal asymptotes for <math>\qquad y = \frac{x + 4}{(x - 3)(x + 2)}</math> | <span class="exam"> Find all vertical and horizontal asymptotes for <math>\qquad y = \frac{x + 4}{(x - 3)(x + 2)}</math> | ||
| − | == [[ | + | == [[022_Sample_Final_A,_Problem_15|<span class="biglink"><span style="font-size:80%"> Problem 15 </span>]] == |
<span class="exam"> Find the following limit: <math>\qquad \lim_{x \rightarrow -3}\frac{x^2 + 7x + 12}{x^2 - 2x - 14}</math> | <span class="exam"> Find the following limit: <math>\qquad \lim_{x \rightarrow -3}\frac{x^2 + 7x + 12}{x^2 - 2x - 14}</math> | ||
Revision as of 12:09, 30 May 2015
This is a sample, and is meant to represent the material usually covered in Math 22 for the second exam. An actual test may or may not be similar. Click on the boxed problem numbers to go to a solution.
Problem 1
Find all first and second partial derivatives of the following function, and demostrate that the mixed second partials are equal:
Problem 2
A dairy farmer plans to enclose a rectangular pasture adjacent to a river. To provide enough grass for the her, the pasure must contain 200 square meters of grass. No fencing is required along the river. What dimensions will use the smallest amount of fencing?
Problem 3
Find the antiderivative:
Problem 4
Use implicit differentiation to find
Problem 5
Find producer and consumer surpluses for the following situation:
Problem 6
Sketch the curve, including all relative exterma and points of inflection.
Problem 7
Find the present value of the income stream from now until 5 years from now, given an interest rate (note that once you plug in the limits of integration, you are finished- you do not need to simplify our answer beyond that step).
Problem 8
Find ther marginial productivity of labor and marginal productivity of capital for the following Cobb-Douglas productio function: (note: you must simplify so your solution does not contain negative exponents)
Problem 9
Given demand , and cost , find:
- a) Marginal revenue when x = 7 units.
- b) The quantity(x-value) that produces minimum average cost.
- c) Maximum profit (find the x-value and the profit itself)
Problem 10
Set up the formula to find the amount of money one would have at the end of 8 years if she invests $2100 in an account paying 6% annual interest, compounded quarterly.
Problem 11
Find the derivative: (note: you do not need to simplify the derivative after finding it)
Problem 12
Find the antiderivative:
Problem 13
Use differentials to find given
Problem 14
Find all vertical and horizontal asymptotes for
Problem 15
Find the following limit:
