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Chapter 11: Problem 3

The production function for a firm in the business of calculator assembly is given by \\[ q=2 \sqrt{l} \\] where \(q\) denotes finished calculator output and \(l\) denotes hours of labor input. The firm is a price-taker both for calculators (which sell for \(P\) ) and for workers (which can be hired at a wage rate of \(w\) per hour). a. What is the total cost function for this firm? b. What is the profit function for this firm? c. What is the supply function for assembled calculators \\[ [q(P, w)] ? \\] d. What is this firm's demand for labor function \([l(P, w)] ?\) e. Describe intuitively why these functions have the form they do.

Short Answer

Expert verified
Answer: In the calculator assembly firm, the profit function gives the difference between revenue and total costs, considering the production function and the price of each calculator. The supply function shows the optimal level of calculator production, depending on the price and wage rate. The labor demand function shows the relation between the demand for labor input and the price and wage rate. These functions show that the firm's production, labor demand, and supply decisions are influenced by the relationship between the wage rate and the price of the output (calculators).

Step by step solution

01

Calculate the Total Cost function

To calculate the total cost function, we first look at the given production function and wage rate. Since labor is the only input, we only need to consider the wage rate. Variable cost (VC) is the cost of labor, which can be calculated by multiplying the hours of labor input by the wage rate (\(w\)). \\[ VC = w \cdot l \\] Total cost (TC) is the sum of variable costs and fixed costs. Since the problem does not mention any fixed costs, we only have to consider the variable costs: \\[ TC = VC = w \cdot l \\] Now we have the total cost function in terms of labor input (\(l\)).
02

Calculate the Profit function

To calculate the profit function, we need to consider the revenue and total cost. Revenue is given by the price of the calculators (\(P\)) multiplied by the output produced (\(q\)): \\[ R = P \cdot q \\] Since we know the production function (\(q = 2\sqrt{l}\)), we can substitute the expression for \(q\) to get the revenue function in terms of \(l\): \\[ R = P \cdot 2 \sqrt{l} \\] Now, subtract the total cost function (found in step 1) from the revenue function to get the profit function: \\[ \pi(l) = R - TC = P \cdot 2 \sqrt{l} - w \cdot l \\]
03

Derive the Supply function

To find the supply function, we need to determine the profit-maximizing level of output (\(q\)) as a function of the price (\(P\)) and wage rate (\(w\)). To maximize the profit, we need to find the level of labor input that maximizes the profit function (found in step 2) and then use the production function to find the corresponding output. Take the first-order condition, i.e., the derivative of the profit function with respect to \(l\) and set it equal to zero: \\[ \frac{d \pi(l)}{d l} = P - \frac{w}{\sqrt{l}} = 0 \\] Solving for \(l\), we get the profit-maximizing labor input: \\[ l^* = \left(\frac{w}{P}\right)^2 \\] Now, substitute the optimal labor input (\(l^*\)) in the production function to get the supply function \(q(P, w)\): \\[ q^* = 2 \sqrt{l^*} = 2 \sqrt{\left(\frac{w}{P}\right)^2} = 2\left(\frac{w}{P}\right) \\]
04

Find the Demand for labor function

We have already found the optimal labor input \(l^*\) in Step 3, which represents the demand for labor, so the demand for labor function is: \\[ l(P, w) = \left(\frac{w}{P}\right)^2 \\]
05

Explain the intuitions behind the functions

- The total cost function is the cost of labor input only since labor is the only input in the production function. The firm faces no fixed costs. - The profit function gives the difference between revenue and total costs, considering the production function and the price of each calculator. - The supply function shows how the optimal level of calculator production depends on the price and wage rate. The intuition is that, as the wage rate increases, the cost of production also increases, which leads the firm to supply a lower level of output. - The labor demand function shows the relation between the demand for labor input and the price and wage rate, which is crucial for the firm's decision-making. When the wage rate is high relative to the price of calculators, the firm will demand less labor input to produce calculators as they seek to manage their costs. - These functions show that this firm's production, labor demand, and supply decisions are influenced by the relationship between the wage rate and the price of the output (calculators).

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Most popular questions from this chapter

Young's theorem can be used in combination with the envelope results in this chapter to derive some useful results. a. Show that \(\partial l(P, v, w) / \partial v=\partial k(P, v, w) / \partial w .\) Interpret this result using substitution and output effects. b. Use the result from part (a) to show how a unit tax on labor would be expected to affect capital input. c. Show that \(\partial q / \partial w=-\partial l / \partial P\). Interpret this result. d. Use the result from part (c) to discuss how a unit tax on labor input would affect quantity supplied.

The demand for any input depends ultimately on the demand for the goods that input produces. This can be shown most explicitly by deriving an entire industry's demand for inputs. To do so, we assume that an industry produces a homogeneous good, \(Q\), under constant returns to scale using only capital and labor. The demand function for \(Q\) is given by \(Q=D(P),\) where \(P\) is the market price of the good being produced. Because of the constant returns-to- scale assumption, \(P=M C=A C .\) Throughout this problem let \(C(v, w, 1)\) be the firm's unit cost function. a. Explain why the total industry demands for capital and labor are given by \(k=Q C_{v}\) and \(l=Q C_{w^{-}}\) b. Show that \\[ \frac{\partial k}{\partial v}=Q C_{v v}+D^{\prime} C_{v}^{2} \quad \text { and } \quad \frac{\partial l}{\partial w}=Q C_{w w}+D^{\prime} C_{w}^{2} \\] c. Prove that \\[ C_{w}=\frac{-w}{v} C_{v w} \quad \text { and } \quad C_{w w}=\frac{-v}{w} C_{v w} \\] d. Use the results from parts (b) and (c) together with the elasticity of substitution defined \(\sigma=C C_{v w} / C_{v} C_{w}\) to show that \\[ \frac{\partial k}{\partial v}=\frac{w l}{Q} \cdot \frac{\sigma k}{v C}+\frac{D^{\prime} k^{2}}{Q^{2}} \text { and } \frac{\partial l}{\partial w}=\frac{v k}{Q} \cdot \frac{\sigma l}{w C}+\frac{D^{\prime} P}{Q^{2}} \\] e. Convert the derivatives in part (d) into elasticities to show that \\[ e_{k, v}=-s_{l} \sigma+s_{k} e_{Q, P} \quad \text { and } \quad e_{l, w}=-s_{k} \sigma+s_{l} e_{Q, P} \\] where \(e_{Q, P}\) is the price elasticity of demand for the product being produced. f. Discuss the importance of the results in part (c) using the notions of substitution and output effects from Chapter 11

Because firms have greater flexibility in the long run, their reactions to price changes may be greater in the long run than in the short run. Paul Samuelson was perhaps the first economist to recognize that such reactions were analogous to a principle from physical chemistry termed the Le Châtelier's Principle. The basic idea of the principle is that any disturbance to an equilibrium (such as that caused by a price change) will not only have a direct effect but may also set off feedback effects that enhance the response. In this problem we look at a few examples. Consider a price-taking firm that chooses its inputs to maximize a profit function of the \\[ \text { form } \Pi(P, v, w)=P f(k, l)-w l-v k . \text { This maximiza- } \\] tion process will yield optimal solutions of the general form \(q^{*}(P, v, w), l^{*}(P, v, w),\) and \(k^{*}(P, v, w) .\) If we constrain capital input to be fixed at \(\bar{k}\) in the short run, this firm's short-run responses can be represented by \(q^{s}(P, w, \bar{k})\) and \(l^{s}(P, w, \bar{k})\) a. Using the definitional relation \(q^{*}(P, v, w)=q^{*}(P, w\) \(\left.k^{\prime \prime}(P, v, w)\right),\) show that $$\frac{\partial q^{*}}{\partial P}=\frac{\partial q^{s}}{\partial P}+\frac{-\left(\frac{\partial k^{*}}{\partial P}\right)^{2}}{\frac{\partial k^{*}}{\partial v}}$$ Do this in three steps. First, differentiate the definitional relation with respect to \(P\) using the chain rule. Next, differentiate the definitional relation with respect to \(v\) (again using the chain rule), and use the result to substitute for \(\partial q^{s} / \partial k\) in the initial derivative. Finally, substitute a result analogous to part (c) of Problem 11.10 to give the displayed equation. b. Use the result from part (a) to argue that \(\partial q^{*} / \partial P \geq\) \(\partial q^{s} / \partial P .\) This establishes Le Châtelier's Principle for supply: Long-run supply responses are larger than (constrained short-run supply responses. c. Using similar methods as in parts (a) and (b), prove that Le Châtelier's Principle applies to the effect of the wage on labor demand. That is, starting from the definitional relation \(l^{*}(P, v, w)=l^{*}\left(P, w, k^{*}(P, v, w)\right),\) show that \(\partial l^{*} / \partial w \leq \partial l^{5} / \partial w,\) implying that long-run labor demand falls more when wage goes up than short-run labor demand (note that both of these derivatives are negative). d. Develop your own analysis of the difference between the short-and long-run responses of the firm's cost function \([C(v, w, q)]\) to a change in the wage \((w)\)

How would you expect an increase in output price, \(P\), to affect the demand for capital and labor inputs? a. Explain graphically why, if neither input is inferior, it seems clear that a rise in \(P\) must not reduce the demand for either factor. b. Show that the graphical presumption from part (a) is demonstrated by the input demand functions that can be derived in the Cobb-Douglas case. c. Use the profit function to show how the presence of inferior inputs would lead to ambiguity in the effect of \(P\) on input demand.

Would a lump-sum profits tax affect the profit-maximizing quantity of output? How about a proportional tax on profits? How about a tax assessed on each unit of output? How about a tax on labor input?
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