Apply the Lagrange multiplier for a firm that faces the production function Q = 2K0.2 L0.6 and can buy L at R240 a unit and K at R4 a unit.(a) If it has a budget of R16,000 what combination of K and L should it use to maximize output? (7)(b) If it is given a target output of 40 units of Q what combination of K and L should it use to minimize the cost of this output?

A consumer spends an amount 𝑚𝑚 to buy 𝑥𝑥 units of one good at the price of 6 per unit and 𝑥𝑥 units of a different good at the price of 10 per unit. Here 𝑚𝑚 is positive and suppose that 8 < 𝑚𝑚 < 40. The consumer’s utility function is 𝑈(𝑥, y) = 𝑥y + y^2+ 2𝑥 + 2y, so that her problem is: Maximize 𝑥y+y^2 +2x+2y subject to 6𝑥+10𝑥y=𝑚 (a) Find the optimal quantities 𝑥∗ and y∗ and the Lagrange multiplier, all of them as functions of 𝑚. (b) Write down the maximum value of the utility function as a function of m. (c) Find the derivative of the above utility function for m=20 (d) What are the solutions for 𝑥∗ and y∗ if (i) 𝑚 ≤ 8? (ii) 𝑚 ≥ 40?

A firm’s total revenue function and total cost function are as follows:TR = 200Q – Q2TC = 50 + 20Q +0.5Q2Use this information the answer the following three questions (Q16-Q18).To maximize total revenue, how much quantity should the firm produce?a.Q = 200b.Q = 100c.Q = 150d.Q = 50To minimize average cost, how much quantity should the firm produce?a.Q = 20b.Q = 10c.Q = 100d.Q = 200To maximize profit, how much quantity should the firm produce? a.Q = 40b.Q = 80c.Q = 60d.Q = 20

Suppose that you are the manager of watch making firm operating in acompetitive market your cost of production is given by C = 100 +Q2 , whereQ is the level of output and C is total cost. The marginal cost ofproduction is 2Q .The fixed cost of production is $100. If the price ofwatches is $ 60, how many watches should you produce to maximizeprofit?

To find the Lagrange multiplier associated with the equality constraint for the given utility maximization problem, follow these steps: 1. **Set up the Lagrangian**: \[ \mathcal{L}(x, y, \lambda) = 5xy + \lambda (30 - 5x - y) \] 2. **Find the partial derivatives and set them to zero**: \[ \frac{\partial \mathcal{L}}{\partial x} = 5y - 5\lambda = 0 \quad \Rightarrow \quad y = \lambda \] \[ \frac{\partial \mathcal{L}}{\partial y} = 5x - \lambda = 0 \quad \Rightarrow \quad \lambda = 5x \] \[ \frac{\partial \mathcal{L}}{\partial \lambda} = 30 - 5x - y = 0 \quad \Rightarrow \quad y = 30 - 5x \] 3. **Substitute \( \lambda \) from the first equation into the second equation**: \[ y = 5x \] 4. **Substitute \( y = 5x \) into the budget constraint**: \[ 5x + 5x = 30 \] \[ 10x = 30 \] \[ x = 3 \] 5. **Find the corresponding \( y \)**: \[ y = 5x = 5 \times 3 = 15 \] 6. **Find the Lagrange multiplier \( \lambda \)**: From the equation \( \lambda = 5x \): \[ \lambda = 5 \times 3 = 15 \] So, the Lagrange multiplier associated with the equality constraint is \( \lambda = 15 \). The correct answer is: - \( 15 \)

In the pursuit for cost minimization to produce quantity Q, at what point does the firm achieve optimality?Question 9Select one:a.Any combination of K and L is optimal.b.By solely focusing on the isocost line.c.Where the isoquant and isocost line cross paths.d.At the maximum level of output achievable with a given cost.