Figure E5.5 - The Outcome under a Tenancy Contract

Deriving Angela's Optimal Choice in a Specific Example by Equating MRS and MRT

Optimal Labor and Consumption Choice

A farmer, Angela, has a utility function over free time (t) and consumption (c) given by u(t, c) = 4√t + c. Her production of grain (which she consumes) is determined by the hours she works (h), according to the production function y = 2√(2h), where h = 24 - t. To find the technically efficient allocation of time and consumption, one must find the point where her subjective trade-off between free time and consumption equals the objective trade-off dictated by the production technology. What is the efficient amount of free time (t) for Angela?

Calculating Economic Rent in a Specific Scenario

A farmer's preferences for free time (t) and consumption of grain (c) are described by the utility function u(t, c) = 4√t + c. The grain is produced according to the production function c = 2√(2(24-t)), where (24-t) is the hours of work. Suppose the farmer is currently working 10 hours a day, which gives her 14 hours of free time. Based on this situation, which of the following statements is correct?

Calculating Consumption on the Reservation Indifference Curve

Calculating Maximum Economic Rent in a Coercive Scenario

A landowner makes a take-it-or-leave-it offer to a farmer. The farmer's preferences for free time (t) and consumption (c) are described by the utility function u(t, c) = 4√t + c. The amount of grain the farmer can produce is a function of her hours of work (h), given by y = 2√(2h), where h = 24 - t. If the farmer rejects the offer, her next best alternative provides a utility of 21. To maximize his income, how many units of grain should the landowner demand as rent?

Evaluating a Tenancy Contract

A landowner wants to determine the maximum rent he can extract from a farmer. The farmer's preferences for free time (t) and consumption (c) are given by the utility function u(t, c) = 4√t + c. The production function for grain is c = 2√(2(24-t)), where (24-t) is hours of work. The farmer's next best alternative provides a utility of 21. Arrange the following steps in the correct logical order to calculate the landowner's maximum possible income.

Evaluating the Efficiency of a Labor Contract

Calculating Economic Rent in a Specific Scenario

A farmer's preferences for free time (t) and consumption of grain (c) are described by the utility function u(t, c) = 4√t + c. The grain is produced according to the production function c = 2√(2(24-t)), where (24-t) is the hours of work. Suppose the farmer is currently working 10 hours a day, which gives her 14 hours of free time. Based on this situation, which of the following statements is correct?

Deriving Angela's Optimal Choice in a Specific Example by Equating MRS and MRT

An individual's preferences for consumption (c) and hours of free time (t) are represented by the utility function u = 4√t + c. Given a choice between two options, which one would this individual prefer?

Option A: 16 hours of free time and a consumption level of 10. Option B: 9 hours of free time and a consumption level of 15.

Interpreting a Utility Function

An individual's preferences for consumption (c) and hours of free time (t) are represented by the utility function u = 4√t + c. What is the marginal rate of substitution (the rate at which this individual is willing to give up units of consumption for an additional hour of free time) when they have 9 hours of free time?

Consider an individual whose preferences for consumption (c) and hours of free time (t) are described by the utility function u = 4√t + c. This individual's willingness to give up consumption for an extra hour of free time is the same regardless of how much consumption they currently have, assuming their amount of free time is held constant.

Evaluating a Policy Change

An individual's preferences for consumption (c) and hours of free time (t) are represented by the utility function u = 4√t + c. Consider two situations:

Situation A: The individual has 9 hours of free time and a consumption level of 20. Situation B: The individual has 9 hours of free time and a consumption level of 30.

How does the individual's willingness to trade consumption for an additional hour of free time (the marginal rate of substitution) compare between these two situations?

Analyzing Preferences from a Utility Function

An individual's preferences for consumption (c) and hours of free time (t) are represented by the utility function u = 4√t + c. This individual is indifferent between two bundles of goods: Bundle X, which consists of 16 hours of free time and a consumption level of 12, and Bundle Y, which consists of 25 hours of free time and an unknown consumption level. What must the consumption level be in Bundle Y for the individual to be indifferent between Bundle X and Bundle Y?

Evaluating a Job Offer

An individual's preferences for consumption (c) and hours of free time (t) are represented by the utility function u = 4√t + c. Which of the following statements accurately describes how this individual values an additional hour of free time?

Deriving Angela's Optimal Choice in a Specific Example by Equating MRS and MRT

An individual's feasible set of outcomes for daily consumption (c) and free time (t) is defined by the production constraint c = 2√(2(24-t)). Which of the following combinations of free time and consumption is feasible but not efficient?

Evaluating Production Choices

Calculating the Marginal Rate of Transformation

An individual's feasible set of outcomes for daily consumption (c) and free time (t) is defined by the production constraint c = 2√(2(24-t)). A combination of 16 hours of free time and 8 units of consumption lies on this feasible frontier.

Interpreting the Shape of the Feasible Frontier

An individual's production possibilities are described by the equation c = 2√(2(24-t)), where 'c' is units of consumption and 't' is hours of free time per day. Match each amount of free time with the corresponding maximum possible amount of consumption, rounded to two decimal places.

An individual's production possibilities are described by the equation c = 2√(2(24-t)), where 'c' is units of consumption and 't' is hours of free time per day. The marginal rate of transformation (MRT) at the point where t=16 is 1. This means that to gain one more hour of free time (from 16 to 17), the individual must give up approximately ____ unit(s) of consumption.

An individual's production possibilities are described by the equation c = 2√(2(24-t)), where 'c' is units of consumption and 't' is hours of free time per day. How does the opportunity cost of one additional hour of free time change as the amount of free time ('t') increases?

An individual's production possibilities are described by the equation c = 2√(2(24-t)), where 'c' is units of consumption and 't' is hours of free time per day. According to this relationship, the amount of consumption that must be given up to gain one additional hour of free time is the same whether the individual is currently taking 10 hours or 20 hours of free time.

Impact of Technological Improvement on Production Possibilities