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§ 1.7. More About Derivatives. Section Outline. Differentiating Various Independent Variables Computing Second Derivatives Second Derivatives Evaluated at a Point Marginal Cost Marginal Revenue Marginal Profit. Differentiating Various Independent Variables. EXAMPLE.
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§1.7 More About Derivatives
Section Outline • Differentiating Various Independent Variables • Computing Second Derivatives • Second Derivatives Evaluated at a Point • Marginal Cost • Marginal Revenue • Marginal Profit
Differentiating Various Independent Variables EXAMPLE Find the first derivative. SOLUTION We first note that the independent variable is t and the dependent variable is T. This is significant inasmuch as they are considered to be two totally different variables, just as x and y are different from each other. We now proceed to differentiate the function. This is the given function. We begin to differentiate. Use the Sum Rule. Use the General Power Rule.
Differentiating Various Independent Variables CONTINUED Finish differentiating. Simplify. Simplify.
Second Derivatives EXAMPLE Find the first and second derivatives. SOLUTION This is the given function. This is the first derivative. This is the second derivative.
Second Derivatives Evaluated at a Point EXAMPLE Compute the following. SOLUTION Compute the first derivative. Compute the second derivative. Evaluate the second derivative at x = 2.
Marginal Cost EXAMPLE Let C(x) be the cost (in dollars) of manufacturing x bicycles per day in a certain factory. Assume C(50) = 5000 and Estimate the cost of manufacturing 51 bicycles per day. SOLUTION We will first use the additional cost formula for manufacturing 1 more bicycle per day beyond the cost of producing 50 bicycles per day. We already know it costs $5000 to produce 50 bicycles per day since C(50) = 5000. So we wish to determine how much more, beyond that $5000, it costs to produce 51 bicycles. Therefore, we estimate the cost of manufacturing 51 bicycles to be $5045.
Marginal Revenue EXAMPLE Suppose the revenue from producing (and selling) x units of a product is given by R(x) = 3x – 0.01x2 dollars. (a) Find the marginal revenue at a production level of 20. (b) Find the production levels where the revenue is $200. SOLUTION (a) Since we are looking for the marginal revenue at a production level of 20, and we have an equation for R(x), we will simply find This is the given revenue function. This is the marginal revenue function. Evaluate the marginal revenue function at x = 20. Therefore, the marginal revenue at a production level of 20 is 2.6.
Marginal Revenue CONTINUED (b) To find the production levels where the revenue is $200 we need to use the revenue function and replace revenue, R(x), with 200 and then solve for x. This is the given revenue function. Replace R(x) with 200. Get everything on the left side of the equation. Multiply everything by 100. Factor. Solve for x. Therefore, the production levels for which revenue is $200 are x = 100 and x = 200 units produced.