Specificity of Partial Derivative Expressions to the Utility Function
The specific mathematical formulas derived when analyzing consumer choice, such as the partial derivatives for optimal consumption and free time, are directly dependent on the particular utility function chosen for the model. Different utility functions will yield different quantitative expressions, even if they illustrate the same general economic principles.
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The Economy 2.0 Microeconomics @ CORE Econ
Ch.3 Doing the best you can: Scarcity, wellbeing, and working hours - The Economy 2.0 Microeconomics @ CORE Econ
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Marginal Utility of Free Time
Marginal Utility of Consumption
Calculus-Based Methods for Analyzing Indifference Curves
Specificity of Partial Derivative Expressions to the Utility Function
An individual's satisfaction from consuming a quantity 'c' of goods and enjoying 't' hours of free time is represented by the utility function U(c, t) = c^2 * t^3. What is the expression for the marginal utility of consumption (c)?
Calculating Marginal Utility of Free Time
Consumer Choice Analysis
An individual's satisfaction from consuming a quantity 'c' of goods and enjoying 't' hours of free time is described by the utility function U(c, t) = 5c + 2√t. Based on this function, which of the following statements is true?
An individual's preferences for consumption (c) and free time (t) are described by the utility function U(c, t) = 10 * ln(c) + 5t. What is the marginal utility of free time (t)?
Consider an individual whose preferences for consumption (c) and free time (t) are represented by the utility function U(c, t) = 2c + 10√t. For this individual, the additional satisfaction gained from one more hour of free time is always greater than the additional satisfaction gained from one more unit of consumption, regardless of their current amounts of consumption and free time.
Match each utility function, which describes an individual's satisfaction from consuming a quantity 'c' of goods and enjoying 't' hours of free time, with its corresponding expression for the marginal utility of free time.
Evaluating Claims about Marginal Utility
Analyzing Diminishing Marginal Utility
Consider an individual's preferences for consumption (c) and free time (t) represented by the utility function U(c, t) = 4c^0.5 * t^0.5. A student calculates the marginal utility of consumption and claims it is equal to 2c^-0.5. This claim is correct.
Learn After
An economist models a consumer's choices between goods A and B using the preference representation U(A, B) = A^0.5 * B^0.5. A second economist models the same consumer's choices using the representation U(A, B) = 2A + 3B. Both economists correctly apply the same optimization principles to find the consumer's optimal consumption bundle given a budget. They arrive at different mathematical expressions for the optimal quantities of A and B. Which statement best explains why their final expressions are different?
Comparing Consumer Preference Models
Impact of Utility Function Form on Derived Expressions
A consumer's preferences for two goods, X and Y, can be represented by different mathematical functions. For each utility function provided, match it to the correct mathematical expression for its marginal rate of substitution (MRS). The MRS is calculated as the ratio of the partial derivative of the utility function with respect to X to the partial derivative with respect to Y.
Reconciling Economic Models
An economist develops a model of a consumer's choice between leisure time (L) and consumption of goods (C), using the utility function U(L, C) = L * C. After applying optimization techniques, they derive a specific mathematical expression for the consumer's optimal amount of leisure. The economist then claims this derived mathematical expression represents a universal rule for how all individuals decide on their leisure time. Which statement best evaluates the economist's claim?
If two distinct mathematical utility functions, U1(X, Y) and U2(X, Y), both successfully represent the same consumer's underlying preference ordering (i.e., for any two bundles, if the consumer prefers bundle A to bundle B, then U1(A) > U1(B) and U2(A) > U2(B)), then the mathematical expressions for the optimal quantities of goods X and Y derived from each function, given the same prices and income, must be identical.
An economist models a consumer's choices between two goods, X and Y, using the preference representation U(X, Y) = X * Y. From this, they derive specific mathematical expressions for the optimal quantities of X and Y. If the economist revises the model to use the representation U(X, Y) = min(X, Y) to reflect that the goods are always consumed together, what is the most direct and certain consequence for the model's derived expressions?
Predicting Model Adjustments for Transportation Choices
Two researchers are modeling a consumer's preferences for two goods, Good 1 and Good 2, with quantities denoted by q1 and q2.
- Researcher A uses the function U(q1, q2) = q1 * q2.
- Researcher B uses the function V(q1, q2) = (q1 * q2)^2.
Both researchers will use partial derivatives to analyze the consumer's choices. Assuming their calculations are correct, which of the following outcomes is most likely?
A consumer's preferences for two goods, X and Y, can be represented by different mathematical functions. For each utility function provided, match it to the correct mathematical expression for its marginal rate of substitution (MRS). The MRS is calculated as the ratio of the partial derivative of the utility function with respect to X to the partial derivative with respect to Y.